[Architecture of receptor-operated ionic channels of biological membranes].

Ion channels of biological membranes are the key proteins, which provide bioelectric functioning of living systems. These proteins are homo- or heterooligomers assembled from several identical or different subunits. Understanding the architectural organization and functioning of ion channels has been significantly extended due to resolving the crystal structure of several types of voltage-gated and receptor-operated channels. This review summarizes the information obtained from crystal structures of potassium, nicotinic acetylcholine receptor, P2X, and other ligand-gated ion channels. Despite the differences in the function, topology, ionic selectivity, and the subunit stoichiometry, a high similarity in the principles of organization of these macromolecular complexes has been revealed.

Fast potentiation of glycine receptor channels of intracellular calcium in neurons and transfected cells.

Inhibitory glycine receptors (GlyRs) are mainly expressed in the spinal cord and in the midbrain, where they control motor and sensory pathways. We describe here a fast potentiation of GlyR by intracellular Ca2+. This phenomenon was observed in rat spinal cord neurons and in transfected human cell lines. Potentiation develops in <100 ms, is proportional to Ca2+ influx, and is characterized by an increase in GlyR apparent affinity for glycine. Phosphorylation and G protein pathways appear not to be involved in the potentiation mechanism. Single-channel recordings in cell-attached and excised patches, as well as whole-cell data suggest the presence of a diffusible cytoplasmic factor that modulates the GlyR channel gating properties. Ca2+-induced potentiation may be important for rapid modulation of glycinergic synapses.

ATP release during cell swelling activates a Ca2+-dependent Cl- current by autocrine mechanism in mouse hippocampal microglia.

Microglia cells, resident immune cells of the brain, survey brain parenchyma by dynamically extending and retracting their processes. Cl- channels, activated in the cellular response to stretch/swelling, take part in several functions deeply connected with microglia physiology, including cell shape changes, proliferation, differentiation and migration. However, the molecular identity and functional properties of these Cl- channels are largely unknown. We investigated the properties of swelling-activated currents in microglial from acute hippocampal slices of Cx3cr1 +/GFP mice by whole-cell patch-clamp and imaging techniques. The exposure of cells to a mild hypotonic medium, caused an outward rectifying current, developing in 5-10 minutes and reverting upon stimulus washout. This current, required for microglia ability to extend processes towards a damage signal, was carried mainly by Cl- ions and dependent on intracellular Ca2+. Moreover, it involved swelling-induced ATP release. We identified a purine-dependent mechanism, likely constituting an amplification pathway of current activation: under hypotonic conditions, ATP release triggered the Ca2+-dependent activation of anionic channels by autocrine purine receptors stimulation. Our study on native microglia describes for the first time the functional properties of stretch/swelling-activated currents, representing a key element in microglia ability to monitor the brain parenchyma.

Protein kinase C modulation of NMDA currents: an important link for LTP induction.

A brief high frequency tetanic stimulation of afferent fibers induces a long-term potentiation (LTP) of synaptic transmission, which is manifested by an increase in the size of the synaptic response elicited by low frequency stimulation of the same synapse. LTP persists for several hours in vitro and up to several weeks in vivo, and is at present the most extensively studied form of activity-dependent synaptic plasticity. This article focuses on the relationship between two key elements in the induction of LTP--the N-methyl-D-aspartate (NMDA) subtype of glutamate receptor and the Ca(2+)-phospholipid-dependent protein kinase C (PKC). In view of several recent findings that describe a direct positive modulation of NMDA currents by PKC, we suggest that PKC activity may, in fact, determine the threshold of LTP induction. Enhanced kinase activity may underlie the central role of the NMDA receptor--channel complex in neuronal plasticity.

[SUBUNIT SPECIFIC MODULATION OF GLYCINE RECEPTORS BY GINKGOLIC ACID.]

Ginkgo biloba extract is a multicomponent pharmacological agent widely used in neurological disorders therapy. It was shown that ginkgolic acid, a constituent of lipophylic Ginkgo biloba extract, has numerous biological activities. In the present study we have focused on the features of ginkgolic acid action on αl and α2 glycine receptors that make part of the inhibitory system of the brain. Using whole-cell configuration of patch-clamp recording we analysed effects of ginkgolic acid on different subunits of glycine receptors. Experiments were performed on cultured Chinese hamster ovary cells (CHO cells), transfected with αl and α2 glycine receptor subunits. Ionic currents were induced by the fast application of different glycine concentrations. After 20-40 sec of pre-treatment with ginkgolic acid (25µM) currents mediated by al glycine receptors reversibly increased from 364±49 pA, (n=34) to 846±134 pA, (n=34). EC(50) for glycine has changed from 36±6 µM (control) to 17±2 µM. In contrast, the application of ginkgolic acid on glycine receptors formed by α2 subunits did not provoke potentiation. Our results demonstrate that ginkgolic acid is a subunit specific modulator of glycine receptors. The mechanisms of the ginkgolic acid action on glycine receptors require further investigation.

AMINOACID RESIDUES INVOLVED IN POSITIVE MODULATION OF αl GLYCINE RECEPTORS BY GINKGOLIC ACID.

Previously, we have shown that ginkgolic acid has an ability to potentiate currents, mediated by αl subunits of glycine receptor. In order to define the mechanism of subunit specific action of ginkgolic acid we have performed comparative analysis of the amino acid sequences of at and α2 subunits of glycine receptor. Amino acids that contribute to the different action of ginkgolic acid on glycine receptors formed by these subunits were determined. Using whole-cell configuration of patch-clamp recording, we have demonstrated that mutation of three residues in α2 subunit for corresponding ones from αl subunit makes α2 receptors sensitive to the potentiation by ginkgolic acid. Currents, mediated by α2 mutant receptors, increased by 89±14% after application of ginkgolic acid. Similarly to ai receptors α2 mutant receptors have shown a decrease in EC50. for glycine under the action of ginkgolic acid. Thus, subunit selectivity of the ginkgolic acid is in strong connection with three amino acid residues that are different in α1 And α2 subunits of glycine receptor.

[GLYCINE RECEPTOR: MOLECULAR ORGANIZATION AND PATHOLOGY].

Glycine receptor is the anion-selective channel, providing fast synaptic transmission in the central nervous system of vertebrates. Together with the nicotinic acetylcholine, GABA and serotonin (5-HT3R) receptors, it belongs to the superfamily of pentameric cys-loop receptors. In this review we briefly describe main functions of these transmembrane proteins, their distribution and molecular architecture. Special attention is paid to recent studies on the molecular physiology of these receptors, as well as on presenting of molecular domains responsible for their dysfunction.

Functional integrity of green fluorescent protein conjugated glycine receptor channels.

The alpha subunit (alphaZ1) of the zebrafish glycine receptor (GlyR) has been N-terminus fused with green fluorescent protein (GFP). We found that both pharmacological and electrophysiological properties of this chimeric alphaZ1-GFP are indistinguishable from those of the wild-type receptor when expressed in Xenopus oocytes and cell lines. The apparent affinities of this receptor for agonists (glycine, taurine and GABA), and the antagonist (strychnine) are unchanged, and single channel kinetics are not altered. In the same expression systems, alphaZ1-GFP was visualized using fluorescence microscopy. Fluorescence was distributed anisotropically across cellular membranes. In addition to the Golgi apparatus and endoplasmic reticulum, its presence was also detected on the plasmalemma, localized at discrete hot-spots which were identified as sites of high membrane turnover. Overall, the preservation in alphaZ1-GFPs of the wild type receptor functional properties makes it a promising new tool for further in situ investigations of GlyR expression, distribution and function.

Kinetics and Mg2+ block of N-methyl-D-aspartate receptor channels during postnatal development of hippocampal CA3 pyramidal neurons.

Voltage-dependent magnesium block of N-methyl-D-aspartate-activated channels, and the N-methyl-D-aspartate component of excitatory synaptic currents were studied in CA3 pyramidal neurons of hippocampal slices from immature (postnatal day 3-8) and adult (postnatal day 25-60) rats. In all neurons studied the kinetics of single-channel openings in cell-attached and inside-out configurations was strongly modulated by extracellular Mg2+, in a voltage-dependent manner. No age-dependent difference in the Mg2+ sensitivity of N-methyl-D-aspartate channels was observed. At physiological concentrations of external Mg2+ (1.3 mM), N-methyl-D-aspartate components of excitatory synaptic currents measured from immature and adult rats displayed a similar voltage-dependence. In immature neurons (postnatal day 3-6), the N-methyl-D-aspartate component of excitatory postsynaptic currents decay time-course was a single-exponential with an average time-constant of about 300 ms. In neurons from older animals the decay was described by a double-exponential function with both a fast component (tau f, 54-130 ms) and a slow component (tau s, 275-400 ms). With age, the contribution of the fast component increased and the decay time-course of the N-methyl-D-aspartate component of excitatory postsynaptic currents accelerated. It is concluded that the Mg2+ block of N-methyl-D-aspartate channels in CA3 pyramidal neurons does not change with development, but the kinetic properties of N-methyl-D-aspartate receptor channels are developmentally regulated.

A novel glycine receptor alpha Z1 subunit variant in the zebrafish brain.

Alpha subunits of the inhibitory glycine receptor (GlyR) display genetic heterogeneity in mammals and zebrafish. This diversity is increased in mammals by the alternative splicing mechanism. We report here in zebrafish, the characterization of a new alphaZ1 subunit likely arising from alphaZ1 gene by an alternative splice process (alphaZ1L). This novel cDNA possesses 45 supplementary nucleotides at the putative exon2/exon3 boundary. The corresponding protein contains 15 additional amino acids in the NH2-terminal domain. Heterologous expression of homomeric GlyRalphaZ1L in human embryonic kidney-293 cells generates glycine-gated strychnine-sensitive chloride channels with no obvious discrepancy with pharmacological properties of GlyRalphaZ1. Moreover, zinc modulation of glycine-induced currents is identical in alphaZ1 and alphaZ1L glycine receptors. During ontogenesis, simultaneous alphaZ1 and alphaZ1L mRNA synthesis have been observed. Embryonic and adult alphaZ1 and alphaZ1L mRNA expressions are restricted to the CNS. Embryonic alphaZ1L mRNA anatomical pattern of expression is, however, highly restrained and strictly limited to the rostral part of the brain revealing a highly regionalized function of alphaZ1L in the CNS. This report contributes to the characterization of the diversity of glycine receptor isoforms in zebrafish and emphasizes the common mechanism used among vertebrates for creating GlyR variety and specificity.

Isolation and characterization of an alpha 2-type zebrafish glycine receptor subunit.

The complementary DNA for a novel alpha subunit of the glycine receptor, alphaZ2, was isolated from a zebrafish adult brain library. The molecular characteristics, phylogenetic relationships and messenger RNA length of this alphaZ2 subunit show it to be an alpha2-type glycine receptor subunit isoform. The leader peptide however, diverges from those of known glycine receptor alpha isoforms. Recombinantly expressed in Xenopus oocytes, alphaZ2 formed functional glycine receptor channels. These homomeric channels were activated by glycine and taurine, with apparent affinities similar to those reported for zebrafish alphaZ1 glycine receptor, and were also effectively antagonized by nanomolar concentrations of strychnine. However, during prolonged applications of agonists, ionic currents of alphaZ2 receptor channels declined to a much lower steady-state level than those of alphaZ1, indicating different desensitization properties. Analysis of messenger RNA revealed that alphaZ2 is specifically expressed in adult brain tissue and present in both adult and embryonic zebrafish. This report contributes to the characterization of the diversity of glycine receptor isoforms in vertebrates.

Cloning, expression and electrophysiological characterization of glycine receptor alpha subunit from zebrafish.

The glycine receptor is a ligand-gated anion channel protein, providing inhibitory drive within the nervous system. We report here the isolation and functional characterization of a novel alpha subunit (alphaZ1) of the glycine receptor from adult zebrafish (Danio rerio) brain. The predicted amino acid sequence is 86%, 81% and 77% identical to mammalian isoforms alpha1, alpha3 and alpha2, respectively. AlphaZ1 exhibits many of the molecular features of mammalian alpha1, but the sequence patterns in the M4 and C-terminal domains are more similar to alpha2/alpha3. Phylogenetic analysis indicates that alphaZ1 is more closely related to the mammalian alpha1 subunits, being positioned, however, on a distinct branch. The alphaZ1 messenger RNA is 9.5 kb, similar to that described previously for alpha1 messenger RNAs. When expressed in Xenopus oocytes or a human cell line (BOSC 23), alphaZ1 forms a homomeric receptor which is activated by glycine and antagonized by strychnine. This receptor demonstrates unexpectedly high sensitivity to taurine and can also be activated by GABA. These results are consistent with physiological findings in lamprey and goldfish, and they suggest that this teleost fish glycine receptor displays a lower selectivity to neurotransmitters than that reported for glycine mammalian receptors.

Sensitivity of stretch-activated K+ channels changes during cell-cleavage cycle and may be regulated by cAMP-dependent protein kinase.

The properties of stretch-activated K+ channels in the membrane of loach (Misgurnus fossilis) embryos were studied using the patch-clamp technique. It was found that in the early stages of embryogenesis (2-256 cells) the stretch sensitivity of stretch-activated (SA) channels changes dramatically during the cell cleavage cycle. At the beginning of interphase the stretch sensitivity of SA channels and the probability of being in the open state (P0) were minimal, whereas at prometaphase they were increased 10-100-fold. Application of ATP to the cytoplasmic surface of excised inside-out patches induced a reversible increase in resting P0 and of stretch sensitivity of the SA channels in 50% of the patches, but the non-hydrolysable analogue of ATP, 5'-adenylylimidodiphosphate (AMP-PNP), was not effective. Phosphatase inhibitors (orthovanadate and para-nitrophenyl phosphate) prolonged the effect of ATP. Combined application of ATP, cAMP and cAMP-dependent protein kinase (PK) induced a reversible increase in the SA channel activity in 70% of those excised patches which did not respond to ATP. Inhibitors of PK prevented its activating effect. Dibutyryl-cAMP (dB cAMP) transiently increased activity of SA channels in intact cells. These results suggest that activity of SA channels may be regulated through cAMP-dependent phosphorylation and thus provide the basis for explanation of stretch sensitivity modulation during the cell cycle.

Kinetic differences between Ca(2+)-dependent K+ channels in smooth muscle cells isolated from normal and atherosclerotic human aorta.

The properties of large conductance Ca(2+)-dependent K+ channels in smooth muscle cells (SMC) isolated from normal and atherosclerotic human aorta were studied using the patch-clamp technique. It was shown that SMC from normal human aorta possess a homogeneous population of normal Ca(2+)-dependent K+ channels. In atherosclerotic aorta two kinetically different types of these channels could be distinguished: along with normal 'long' (L)-type channels there appeared channels of 'short' (s)-type. Under similar conditions s-type channels had about a four times shorter mean open time. About five times higher [Ca2+]in was necessary for s-type channels to reach the probability of the channels being open equal to L-type channels. No differences in conductance and voltage dependency were found between the two channel types. Channels of the s-type resembled those previously described in SMC isolated from foetal human aorta. Thus, it can be suggested that during the development of atherosclerosis a population of SMC with s-type Ca(2+)-dependent K+ channels appears in human aorta.

Histamine-induced inward currents in cultured endothelial cells from human umbilical vein.

1. The membrane response to applied histamine of cultured endothelial cells from human umbilical vein was studied by use of whole cell and single channel patch clamp techniques. A value of -27 +/- 1.4 mV was found for the resting potential under whole cell current clamp. No voltage-gated currents were seen at either the macroscopic or single channel levels. 2. At holding potentials of -20 to -40 mV, histamine evoked slow rising, long lasting whole cell inward currents. The inward current was associated with depolarization and decreased input resistance. The calcium ionophore A23187 provoked similar whole cell inward currents. 3. Single channel currents were observed in cell-attached and inside-out patches for both histamine and A23187. The single channel conductance was about 20 pS with a mean open time of 5 ms and a reversal potential of 0 mV in symmetrical potassium solutions. Internal sodium blocked outward going currents. 4. For cell-attached patches, histamine-dependent channel activity required external calcium and was also seen when histamine was present in the bath but not the pipette. Recording from inside-out patches revealed that decreases in 'internal' calcium resulted in the disappearance of channel activity. 5. The histamine-dependent inward current appears to involve calcium-dependent activation of cationic channels.

Regulation of potassium conductance in the cellular membrane at early embryogenesis.

At the early stages of development of the fresh water fish loach (Misgurnus fossilis) the resting membrane potential (Er) of cleaving cells oscillates periodically with an amplitude of 8-12 mV. Er oscillation correlates with the cell cycle and is accompanied by changes of K+ conductivity. Two types of K(+)-selective ionic channels with conductance of approximately 70 and 25 pS in symmetrical (150 mM KCl) solution were observed in the membrane of cleaving loach embryos. 'High' conductance and 'low' conductance channels were recorded in approximately 90% and 10% of patches investigated (n = 275), respectively? The activity of 'high' conductance channels was regulated by the application of pressure to the membrane, ie these channels were stretch-activated (SA). The activity of SA channels changes dramatically during the cell-cleavage cycle. At the beginning of interphase the probability of SA channels being in the open state (P0) was minimal, while at prometaphase the probability was increased 10-100-fold. Application of ATP to the cytoplasmic inside-out patches induced a reversible elevation of stretch sensitivity of the SA channels in 50% of the patches, while the non-hydrolyzable analogue of ATP was not effective. Combined application of ATP, cAMP and cAMP-dependent protein kinase (PK) induced a reversible elevation in the SA channel activity while inhibitors of PK prevented its activating effects. Phosphatase inhibitors prolonged the activating effect of PK on SA channels. We propose that oscillations of the resting potential during the cell-cleavage cycle arise due to modulation of SA channel sensitivity to stretch through cAMP-dependent phosphorylation.

Electrophysiological and pharmacological properties of GluR1, a subunit of a glutamate receptor-channel expressed in Xenopus oocytes.

A cDNA clone encoding an excitatory amino acid receptor was isolated from a rat brain cDNA library by Hollmann et al. (Nature, 342 (1989) 643-648). In Xenopus oocytes, this clone, GluR1, expressed a functional receptor-channel activated by kainate (KA), domoate (D), glutamate and quisqualate (QA). The apparent affinity (EC50) for QA (0.1 microM) was higher than that for KA (50 microM). The maximal response to QA was about 1/10 of that to KA. QA inhibited the KA induced current. The N-methyl-D-aspartate (non-NMDA) receptor antagonist 6,7-dinitroquinoxaline-2,3 dione (DNQX) competitively blocked the effects of both agonists. Currents induced by KA, QA and D in oocytes expressing GluR1 showed identical voltage sensitivities. GluR1 and KA receptor-channels expressed from rat striatum poly(A)+ RNA showed the same ionic selectivity, being permeable mostly to Na+ and K+. The current-voltage relationships of GluR1 showed a strong inward rectification, whereas those of KA receptor-channels expressed from poly(A)+ RNA from various rat brain regions were more linear.

A role for intracellular zinc in glioma alteration of neuronal chloride equilibrium.

Glioma patients commonly suffer from epileptic seizures. However, the mechanisms of glioma-associated epilepsy are far to be completely understood. Using glioma-neurons co-cultures, we found that tumor cells are able to deeply influence neuronal chloride homeostasis, by depolarizing the reversal potential of γ-aminobutyric acid (GABA)-evoked currents (EGABA). EGABA depolarizing shift is due to zinc-dependent reduction of neuronal KCC2 activity and requires glutamate release from glioma cells. Consistently, intracellular zinc loading rapidly depolarizes EGABA in mouse hippocampal neurons, through the Src/Trk pathway and this effect is promptly reverted upon zinc chelation. This study provides a possible molecular mechanism linking glioma invasion to excitation/inhibition imbalance and epileptic seizures, through the zinc-mediated disruption of neuronal chloride homeostasis.

Calibration and functional analysis of three genetically encoded Cl(-)/pH sensors.

Monitoring of the intracellular concentrations of Cl(-) and H(+) requires sensitive probes that allow reliable quantitative measurements without perturbation of cell functioning. For these purposes the most promising are genetically encoded fluorescent biosensors, which have become powerful tools for non-invasive intracellular monitoring of ions, molecules, and enzymatic activity. A ratiometric CFP/YFP-based construct with a relatively good sensitivity to Cl(-) has been developed (Markova et al., 2008; Waseem et al., 2010). Recently, a combined Cl(-)/pH sensor (ClopHensor) opened the way for simultaneous ratiometric measurement of these two ions (Arosio et al., 2010). ClopHensor was obtained by fusion of a red-fluorescent protein (DsRed-monomer) to the E(2)GFP variant that contains a specific Cl(-)-binding site. This construct possesses pK a = 6.8 for H(+) and K d in the 40-50 mM range for Cl(-) at physiological pH (~7.3). As in the majority of cell types the intracellular Cl(-) concentration ([Cl(-)] i ) is about 10 mM, the development of sensors with higher sensitivity is highly desirable. Here, we report the intracellular calibration and functional characterization of ClopHensor and its two derivatives: the membrane targeting PalmPalm-ClopHensor and the H148G/V224L mutant with improved Cl(-) affinity, reduced pH dependence, and pK a shifted to more alkaline values. For functional analysis, constructs were expressed in CHO cells and [Cl(-)] i was changed by using pipettes with different Cl(-) concentrations during whole-cell recordings. K d values for Cl(-) measured at 33°C and pH ~7.3 were, respectively, 39, 47, and 21 mM for ClopHensor, PalmPalm-ClopHensor, and the H148G/V224L mutant. PalmPalm-ClopHensor resolved responses to activation of Cl(-)-selective glycine receptor (GlyR) channels better than did ClopHensor. Our observations indicate that these different ClopHensor constructs are promising tools for non-invasive measurement of [Cl(-)] i in various living cells.