A role for the 2' residue in the second transmembrane helix of the GABA A receptor gamma2S subunit in channel conductance and gating.

GABA(A) receptors composed of alpha, beta and gamma subunits display a significantly higher single-channel conductance than receptors comprised of only alpha and beta subunits. The pore of GABA(A) receptors is lined by the second transmembrane region from each of its five subunits and includes conserved threonines at the 6', 10' and 13' positions. At the 2' position, however, a polar residue is present in the gamma subunit but not the alpha or beta subunits. As residues at the 2', 6' and 10' positions are exposed in the open channel and as such polar channel-lining residues may interact with permeant ions by substituting for water interactions, we compared both the single-channel conductance and the kinetic properties of wild-type alpha1beta1 and alpha1beta1gamma2S receptors with two mutant receptors, alphabetagamma(S2'A) and alphabetagamma(S2'V). We found that the single-channel conductance of both mutant alphabetagamma receptors was significantly decreased with respect to wild-type alphabetagamma, with the presence of the larger valine side chain having the greatest effect. However, the conductance of the mutant alphabetagamma receptors remained larger than wild-type alphabeta channels. This reduction in the conductance of mutant alphabetagamma receptors was observed at depolarized potentials only (E(Cl) = -1.8 mV), which revealed an asymmetry in the ion conduction pathway mediated by the gamma2' residue. The substitutions at the gamma2' serine residue also altered the gating properties of the channel in addition to the effects on the conductance with the open probability of the mutant channels being decreased while the mean open time increased. The data presented in this study show that residues at the 2' position in M2 of the gamma subunit affects both single-channel conductance and receptor kinetics.

Dengue virus M protein C-terminal peptide (DVM-C) forms ion channels.

A chemically synthesized peptide consisting of the C-terminus of the M protein of the Dengue virus type 1 strain Singapore S275/90 (DVM-C) produced ion channel activity in artificial lipid bilayers. The channels had a variable conductance and were more permeable to sodium and potassium ions than to chloride ions and more permeable to chloride ions than to calcium ions. Hexamethylene amiloride (100 microM) and amantadine (10 microM), blocked channels formed by DVM-C. Ion channels may play an important role in the life cycle of many viruses and drugs that block these channels may prove to be useful antiviral agents.

An amino-acid substitution in the influenza-B NB protein affects ion-channel gating.

The effects of site-directed mutations in NB, a protein encoded by the influenza B virus that has been shown to form cation-selective ion channels at pH 6.0, were studied on ion channel characteristics in artificial lipid bilayers. It was thought that the residues in the hydrophobic region of NB we selected for mutation might be involved in the transport of cations across the channel and that changes in these residues might affect channel properties such as gating and ion-selectivity. Serine residues at positions 20 and 28, threonine at position 24 and cysteine at position 26 were replaced by alanine. We found that the mutation S20A gave channels that did not gate and that remained open most of the time. Proton permeability of NB channels, as detected by fluorescence quenching, was also altered by the mutation S20A: channels were no longer proton-permeable. The other mutations, S28A, T24A and C26A, did not have any detectable effect on the activity or proton permeability of channels formed by NB. The results indicate that serine 20 may have an important role in normal function of NB channels.

Cation-selective ion channels formed by p7 of hepatitis C virus are blocked by hexamethylene amiloride.

A 63 residue peptide, p7, encoded by hepatitis C virus was synthesised and tested for ion channel activity in lipid bilayer membranes. Ion channels formed by p7 had a variable conductance: some channels had conductances as low as 14 pS. The reversal potential of currents flowing through the channels formed by p7 showed that they were permeable to potassium and sodium ions and less permeable to calcium ions. Addition of Ca(2+) to solutions made channels formed by p7 less potassium- or sodium-selective. Hexamethylene amiloride, a drug previously shown to block ion channels formed by Vpu encoded by HIV-1, blocked channels formed by p7. In view of the increasing number of peptides encoded by viruses that have been shown to form ion channels, it is suggested that ion channels may play an important role in the life cycle of many viruses and that drugs that block these channels may prove to be useful antiviral agents.

GABA concentration sets the conductance of delayed GABAA channels in outside-out patches from rat hippocampal neurons.

GABAA channels were activated by GABA in outside-out patches from rat cultured hippocampal neurons. They were blocked by bicuculline and potentiated by diazepam. In 109 of 190 outside-out patches, no channels were active before exposure to GABA (silent patches). The other 81 patches showed spontaneous channel activity. In patches containing spontaneous channel activity, rapid application of GABA rapidly activated channels. In 93 of the silent patches, channels could be activated by GABA but only after a delay that was sometimes as long as 10 minutes. The maximum channel conductance of the channels activated after a delay increased with GABA concentration from less than 10 pS (0.5 microm GABA) to more than 100 pS (10 mm GABA). Fitting the data with a Hill-type equation gave an EC50 value of 33 microm and a Hill coefficient of 0.6. The channels showed outward rectification and were chloride selective. In the presence of 1 microm diazepam, the GABA EC50 decreased to 0.2 microm but the maximum conductance was unchanged. Diazepam decreased the average latency for channel opening. Bicuculline, a GABA antagonist, caused a concentration-dependent decrease in channel conductance. In channels activated with 100 microm GABA the bicuculline IC50 was 19 microm. The effect of GABA on channel conductance shows that the role of the ligand in GABAA receptor channel function is more complex than previously thought.

Oxygen-sensing persistent sodium channels in rat hippocampus.

1. Persistent sodium channel activity was recorded before and during hypoxia from cell-attached and inside-out patches obtained from cultured hippocampal neurons at a pipette potential (Vp) of +30 mV. Average mean current (IU) of these channels was very low under normoxic conditions and was similar in cell-attached and excised inside-out patches (-0.018 +/- 0.010 and -0.025 +/- 0.008 pA, respectively, n = 24). 2. Hypoxia increased the activity of persistent sodium channels in 10 cell-attached patches (IU increased from -0. 026 +/- 0.016 pA in control to -0.156 +/- 0.034 pA during hypoxia, n = 4, P = 0.013). The increased persistent sodium channel activity was most prominent at a VP between +70 and +30 mV (membrane potential, Vm = -70 to -30 mV) and could be blocked by lidocaine, TTX or R56865 (n = 5). Sodium cyanide (NaCN, 5 mM; 0.5-5 min) increased persistent sodium channel activity in cell-attached patches (n = 3) in a similar manner. 3. Hypoxia also increased sodium channel activity in inside-out patches from hippocampal neurons. Within 2-4 min of exposure to hypoxia, I had increased 9-fold to -0. 18 +/- 0.04 pA (n = 21, P = 0.001). Sodium channel activity increased further with longer exposures to hypoxia. 4. The hypoxia-induced sodium channel activity in inside-out patches could be inhibited by exposure to 10-100 microM lidocaine applied via the bath solution (I = -0.03 +/- 0.01 pA, n = 8) or by perfusion of the pipette tip with 1 microM TTX (I = -0.01 +/- 0.01 pA, n = 3). 5. The reducing agent dithiothreitol (DTT, 2-5 mM) rapidly abolished the increase in sodium channel activity caused by hypoxia in excised patches (I = -0.01 +/- 0.01 pA, n = 4). Similarly, reduced glutathione (GSH, 5-20 mM) also reversed the hypoxia-induced increase in sodium channel activity (IU = -0.02 +/- 0.02 pA, n = 5). 6. These results suggest that persistent sodium channels in neurons can sense O2 levels in excised patches of plasma membrane. Hypoxia triggers an increase in sodium channel activity. The redox reaction involved in increasing the sodium channel activity probably occurs in an auxiliary regulatory protein, co-localized in the plasma membrane.

Bicuculline, pentobarbital and diazepam modulate spontaneous GABA(A) channels in rat hippocampal neurons.

Spontaneously opening, chloride-selective channels that showed outward rectification were recorded in ripped-off patches from rat cultured hippocampal neurons and in cell-attached patches from rat hippocampal CA1 pyramidal neurons in slices. In both preparations, channels had multiple conductance states and the most common single-channel conductance varied. In the outside-out patches it ranged from 12 to 70 pS (Vp=40 mV) whereas in the cell-attached patches it ranged from 56 to 85 pS (-Vp=80 mV). Application of GABA to a patch showing spontaneous channel activity evoked a rapid, synchronous activation of channels. During prolonged exposure to either 5 or 100 microM GABA, the open probability of channels decreased. Application of GABA appeared to have no immediate effect on single-channel conductance. Exposure of the patches to 100 microM bicuculline caused a gradual decrease on the single-channel conductance of the spontaneous channels. The time for complete inhibition to take place was slower in the outside-out than in the cell-attached patches. Application of 100 microM pentobarbital or 1 microM diazepam caused 2 - 4 fold increase in the maximum channel conductance of low conductance (<40 pS) spontaneously active channels. The observation of spontaneously opening GABA(A) channels in cell-attached patches on neurons in slices suggests that they may have a role in neurons in vivo and could be an important site of action for some drugs such as benzodiazepines, barbiturates and general anaesthetics.

Pentobarbital modulates gamma-aminobutyric acid-activated single-channel conductance in rat cultured hippocampal neurons.

We examined the effect of a range of pentobarbital concentrations on 0.5 microM gamma-aminobutyric acid (GABA)-activated channels (10 +/- 1 pS) in inside-out or outside-out patches from rat cultured hippocampal neurons. The conductance increased from 12 +/- 4 to 62 +/- 9 pS as the pentobarbital concentration was raised from 10 to 500 microM and the data could be fitted by a Hill-type equation. At 100 microM pentobarbital plus 0.5 microM GABA, the conductance seemed to reach a plateau. The pentobarbital EC(50)(0.5 microM GABA) value was 22 +/- 4 microM and n was 1.9 +/- 0.5. In 1 mM pentobarbital plus 0.5 microM GABA, the single-channel conductance decreased to 34 +/- 8 pS. This apparent inhibition of channel conductance was relieved by 1 microM diazepam. The channel conductance was 64 +/- 6 pS in the presence of all three drugs. The channels were open more in the presence of both GABA and pentobarbital than in the presence of either drug alone. Pentobarbital alone (100 microM) activated channels with conductance (30 +/- 2 pS) and kinetic properties distinct from those activated by either GABA alone or GABA plus pentobarbital. Whether pentobarbital induces new conformations or promotes conformations observed in the presence of GABA alone cannot be determined from our study, but the results clearly show that it is the combination of drugs present that determines the single-channel conductance and the kinetic properties of the receptors.

Mutating the highly conserved second membrane-spanning region 9' leucine residue in the alpha(1) or beta(1) subunit produces subunit-specific changes in the function of human alpha(1)beta(1) gamma-aminobutyric Acid(A) receptors.

The properties of the human alpha(1)beta(1) gamma-aminobutyric acid (GABA)(A) receptors were investigated after mutation of a highly conserved leucine residue at the 9' position in the second membrane-spanning region (TM2). The role of this residue in alpha(1) and beta(1) subunits was examined by mutating the 9' leucine to phenylalanine, tyrosine, or alanine. The mutations were in either the alpha(1) subunit (alpha*beta), the beta(1) subunit (alphabeta*), or in both subunits (alpha*beta*), and the receptors were expressed in Sf9 cells. Our results show that the rate of desensitization is increased as the size and hydrophobicity of the 9' residue in the alpha(1) subunit is increased: Y, F > L > A, T. Mutation of L9' in only the beta(1) subunit (alphabeta*) to either phenylalanine or tyrosine increased the EC(50) value for GABA at least 100 times, but the EC(50) was unchanged in alphabeta* alanine mutants. In the 9' alpha(1) mutants (alpha*beta, alpha*beta*) the GABA EC(50) was minimally affected. In alpha*beta and alpha*beta*, but not alphabeta*, the peak currents evoked by millimolar concentrations of GABA were greatly reduced. The reduction in currents could only be partially accounted for by decreased expression of the receptors These findings suggest different roles for the two types of subunits in GABA activation and later desensitization of alpha(1)beta(1) receptors. In addition, an increase in the resting membrane conductance was recorded in alanine but not in phenylalanine and tyrosine mutants, indicating that the side chain size at the 9' position is a major determinant of current flow in the closed conformation.

Spontaneously opening GABA(A) channels in CA1 pyramidal neurones of rat hippocampus.

Spontaneous, single channel, chloride currents were recorded in 48% of cell-attached patches on neurones in the CA1 region of rat hippocampal slices. In some patches, there was more than 1 channel active. They showed outward rectification: both channel conductance and open probability were greater at depolarized than at hyperpolarized potentials. Channels activated by gamma-aminobutyric acid (GABA) in silent patches on the same neurones had similar conductance and outward rectification. The spontaneous currents were inhibited by bicuculline and potentiated by diazepam. It was concluded that the spontaneously opening channels were constitutively active, nonsynaptic GABA(A) channels. Such spontaneously opening GABA(A) channels may provide a tonic inhibitory mechanism in these cells and perhaps in other cells that have GABA(A) receptors although not having a GABA(A) synaptic input. They may also be a target for clinically useful drugs such as the benzodiazepines.

Mutant human alpha(1)beta(1)(T262Q) GABA(A) receptors are directly activated but not modulated by pentobarbital.

Pentobarbital activates GABA(A) receptors and enhances GABA-activated currents. A threonine residue (262) in the second membrane spanning region at the 12' position in the beta(1) subunit, alpha(1)beta(1)(T12'Q), is necessary for the potentiating action of pentobarbital. We examined whether T12'Q-mutated receptors expressed in Spodoptera frugipedra (Sf 9) cells responded to direct activation by pentobarbital. In both mutant and wild type receptors, pentobarbital (100 microM to 1 mM) evoked a current response. The pentobarbital EC(50) values were similar; 119 and 158 microM for alpha(1)beta(1) and alpha(1)beta(1)(T12'Q) receptors, respectively. The results show it is possible to discriminate between agonistic and potentiating effects of pentobarbital, suggesting these actions involve separate mechanisms.

Nitric oxide increases persistent sodium current in rat hippocampal neurons.

1. The effects of nitric oxide (NO) donors on whole-cell, TTX-sensitive sodium currents and single sodium channels in excised patches were examined in rat hippocampal neurons. The whole-cell sodium current consisted of a large transient component (INa,t) and a smaller, inactivation-resistant, persistent component (INa,p). 2. In acutely dissociated neurons, the amplitude of the whole-cell INa, p increased by 60-80 % within a few minutes of exposure to either of two NO donors, sodium nitroprusside (SNP, 100 microM) or S-nitroso-N-acetyl-DL-penicillamine (SNAP, 100 microM). 3. The amplitude of INa,t was not changed significantly by the same concentrations of SNP and SNAP, indicating that NO had a selective effect on INa,p. 4. Both NO donors significantly increased the mean persistent current in excised inside-out patches from cultured hippocampal neurons. SNP at 10-100 microM increased average mean persistent current at a pipette potential (Vp) of +30 mV from -0.010 +/- 0.014 pA (control) to -2.91 +/- 1.41 pA (n = 10). SNAP at 3-100 microM increased the average mean inward current in six inside-out patches from -0.07 +/- 0.02 to -0.30 +/- 0.08 pA (Vp = +30 mV). 5. The increase in persistent Na+ channel activity recorded in inside-out patches in the presence of SNP or SNAP could be reversed by the reducing agent dithiothreitol (DTT, 2-5 mM) or by lidocaine (1-10 microM). 6. The average mean current recorded in the presence of SNP was 10-fold higher than that elicited by SNAP. The time delay before an increase was observed was shorter with SNP (4.0 +/- 0.8 min, n = 8) than with SNAP (8.4 +/- 1.6 min, n = 7). 7. A component of the SNP molecule added on its own, 5 mM sodium cyanide (NaCN), increased mean current in excised inside-out patches (Vp = +30 mV) from -0.06 +/- 0.04 to -0.58 +/- 0.21 pA (n = 19). This increase in channel activity could be blocked by 10 microM lidocaine and 2-5 mM DTT. 8. These results suggest that NO may directly increase the activity of neuronal persistent Na+ channels, but not transient Na+ channels, through an oxidizing action directly on the channel protein or on a closely associated regulatory protein in the plasma membrane.

A threonine residue in the M2 region of the beta1 subunit is needed for expression of functional alpha1beta1 GABA(A) receptors.

Although there is a high degree of homology in the M2 transmembrane segments of alpha1 and beta1 subunits, subunit-specific effects were observed in alpha1beta1 GABA(A) receptors expressed in Spodoptera frugipedra (Sf9) cells when the conserved 13' threonine residue in the M2 transmembrane region was mutated to alanine. When threonine 263 (13') was mutated to alanine in the beta1 subunit, high-affinity muscimol binding and the response to GABA were abolished. This did not occur when the threonine 263 (13') was mutated to alanine in the alpha1 subunit, but the rate of desensitisation increased and the effect of bicuculline, a competitive inhibitor, was reduced. The results show differential effects of subunits on receptor function and support a role for M2 in desensitisation.

The amino-terminal region of Vpr from human immunodeficiency virus type 1 forms ion channels and kills neurons.

We have previously reported that the accessory protein Vpr from human immunodeficiency virus type 1 forms cation-selective ion channels in planar lipid bilayers and is able to depolarize intact cultured neurons by causing an inward sodium current, resulting in cell death. In this study, we used site-directed mutagenesis and synthetic peptides to identify the structural regions responsible for the above functions. Mutations in the N-terminal region of Vpr were found to affect channel activity, whereas this activity was not affected by mutations in the hydrophobic region of Vpr (amino acids 53 to 71). Analysis of mutants containing changes in the basic C terminus confirmed previous results that this region, although not necessary for ion channel function, was responsible for the observed rectification of wild-type Vpr currents. A peptide comprising the first 40 N-terminal amino acids of Vpr (N40) was found to be sufficient to form ion channels similar to those caused by wild-type Vpr in planar lipid bilayers. Furthermore, N40 was able to cause depolarization of the plasmalemma and cell death in cultured hippocampal neurons with a time course similar to that seen with wild-type Vpr, supporting the idea that this region is responsible for Vpr ion channel function and cytotoxic effects. Since Vpr is found in the serum and cerebrospinal fluids of AIDS patients, these results may have significance for AIDS pathology.

Signal transmission in ligand-gated receptors.

At synapses, a transmitter released from a pre-synaptic terminal binds to specific, ligand-gated receptors in the post-synaptic membrane to open up ion channels through the receptor molecules. The flow of ions through these channels generates electrical signals. Electrophysiological techniques have been used over the past 50 years to understand transmission of these signals at synapses. The most recent of these, the patch-clamp technique, allows very small picoamp currents through single-channel molecules to be recorded but gives little information about receptor structure or how drugs influence their function. Now, the subunits of most ligand-gated ion channels have been cloned and sequenced. Cryo-electronmicroscopy has revealed the structure of the ion channel activated by nicotinic agonists. It is pentameric and only a small part of it is in the membrane. In spite of this simple structure, the conductance of chloride channels activated by gamma-aminobutyric acid (GABA(A) channels) is very variable and can be increased markedly by drugs such as diazepam. Site-directed mutagenesis and labelling of cysteine residues in the open and the closed states are being used to define the residues that line the ion channel. Similar methods are being used to find the way in which drugs such as general anaesthetics modulate the function of GABA(A) receptors.

Inhibition of oxidative metabolism increases persistent sodium current in rat CA1 hippocampal neurons.

1. Whole-cell patch-clamp recordings from freshly dissociated rat CA1 neurons revealed a large transient Na+ current (INa,T) and a smaller, inactivation-resistant persistent Na+ current (INa,P). Both currents could be blocked with TTX. 2. The average current densities of INa,T and INa,P in thirty cells were 111.0 +/- 9.62 and 0.87 +/- 0.13 pA pF-1, respectively. 3. Inhibiting oxidative phosphorylation by adding 5 mM sodium cyanide to the pipette solution significantly increased the amplitude of INa,P but had no significant effect on the amplitude of INa,T. 4. Exposing CA1 neurons to hypoxia for more than 7 min caused an increase in the amplitude of INa,P. There was also a delayed decrease in the amplitude of INa,T. 5. INa,P was more sensitive to the Na+ channel blockers TTX and lidocaine than INa,T. The IC50 for the effect of TTX on INa,P was 9.1 +/- 1.2 nM whereas the IC50 for INa,T was 37.1 +/- 1.2 nM, approximately 4-fold higher. Lidocaine (lignocaine; 1 microM) reduced INa,P to 0.24 +/- 0.15 of control (n = 4) whereas INa,T was essentially unaffected (0.99 +/- 0. 11, n = 4). 6. These results show that INa,P is increased when oxidative metabolism is blocked in CA1 neurons. The persistent influx of Na+ through non-inactivating Na+ channels can be blocked by concentrations of Na+ channel blockers that do not affect INa,T.

Two threonine residues in the M2 segment of the alpha 1 beta 1 GABAA receptor are critical for ion channel function.

The role of three threonine residues in the M2 hydrophobic region of the GABAA receptor has been investigated by replacing these polar residues with alanine at the 6', 10' and 13' positions of M2 in the GABAA alpha 1, and beta 1 subunits and co-expressing the mutated subunits in the baculovirus Sf9 insect cell system. GABA did not elicit a current in cells expressing either the 6' or 13' threonine to the alanine mutants. The mutant subunits formed intact heteromeric GABAA receptors as judged by the binding of [3H] muscimol or the relative level of alpha 1 protein present in the plasma membrane. In contrast, a chloride current was generated by GABA in cells expressing the 10' mutant receptor. However, the current decayed more rapidly to baseline in the continued presence of GABA in the 10' mutant receptor than in the wild type receptor. The results are discussed in terms of the possible roles of the threonine residues in the ion conduction pathway.

Extracellular HIV-1 virus protein R causes a large inward current and cell death in cultured hippocampal neurons: implications for AIDS pathology.

The small HIV-1 accessory protein Vpr (virus protein R) is a multifunctional protein that is present in the serum and cerebrospinal fluid of AIDS patients. We previously showed that Vpr can form cation-selective ion channels across planar lipid bilayers, introducing the possibility that, if incorporated into the membranes of living cells, Vpr might form ion channels and consequently perturb the maintained ionic gradient. In this study, we demonstrate, by a variety of approaches, that Vpr added extracellularly to intact cells does indeed form ion channels. We use confocal laser scanning microscopy to examine the subcellular localization of fluorescently labeled Vpr. Plasmalemma depolarization and damage are examined using the anionic potential-sensitive dye bis(1,3-dibutylbarbituric acid) trimethine oxonol and propidium iodide (PI), respectively, and the effect of Vpr on whole-cell current is demonstrated directly by using the patch-clamp technique. We show that recombinant purified extracellular Vpr associates with the plasmalemma of hippocampal neurons to cause a large inward cation current and depolarization of the plasmalemma, eventually resulting in cell death. Thus, we demonstrate a physiological action of extracellular Vpr and present its mechanistic basis. These findings may have important implications for neuropathologies in AIDS patients who possess significant amounts of Vpr in the cerebrospinal fluid.