Selectivity mechanism of the mechanosensitive channel MscS revealed by probing channel subconducting states.

The mechanosensitive channel of small conductance (MscS) has been characterized at both functional and structural levels and has an integral role in the protection of bacterial cells against hypoosmotic shock. Here we investigate the role that the cytoplasmic domain has in MscS channel function by recording wild-type and mutant MscS single-channel activity in liposome patches. We report that MscS preferentially resides in subconducting states at hyperpolarising potentials when Ca(2+) and Ba(2+) ions are the major permeant cations. In addition, our results indicate that charged residues proximal to the seven vestibular portals and their electrostatic interactions with permeating cations determine selectivity and regulate the conductance of MscS and potentially other channels belonging to the MscS subfamily. Furthermore, our findings suggest a role for mechanosensitive channels in bacterial calcium regulation, indicative of functions other than protection against osmolarity changes that these channels possibly fulfil in bacteria.

Enzymatic activity of albumin shown by coelenterazine chemiluminescence.

Bioluminescence, the emission of light from live organisms, occurs in 18 phyla and is the major communication system in the deep sea. It has appeared independently many times during evolution but its origins remain unknown. Coelenterazine bioluminescence discovered in luminous jellyfish is the most common chemistry causing bioluminescence in the sea, occurring in seven phyla. Sequence similarities between coelenterazine luciferases and photoproteins from different phyla are poor (often < 5%). The aim of this study was to examine albumin that binds organic substances as a coelenterazine luciferase to test the hypothesis that the evolutionary origin of a bioluminescent protein was the result of the formation of a solvent cage containing just a few key amino acids. The results show for the first time that bovine and human albumin catalysed coelenterazine chemiluminescence consistent with a mono-oxygenase, whereas gelatin and haemoglobin, an oxygen carrier, had very weak activity. Insulin also catalysed coelenterazine chemiluminescence and was increased by Zn(2+). Albumin chemiluminescence was heat denaturable, exhibited saturable substrate characteristics and was inhibited by cations that bound these proteins and by drugs that bind to human albumin drug site I. Molecular modelling confirmed the coelenterazine binding site and identified four basic amino acids: lys195, arg222, his242 and arg257, potentially important in binding and catalysis similar to naturally occurring coelenterazine bioluminescent proteins. These results support the 'solvent cage' hypothesis for the evolutionary origin of enzymatic coelenterazine bioluminescent proteins. They also have important consequences in diseases such as diabetes, gut disorders and food intolerance where a mono-oxygenase could affect cell surface proteins.

Bacterial metabolic 'toxins': a new mechanism for lactose and food intolerance, and irritable bowel syndrome.

Lactose and food intolerance cause a wide range of gut and systemic symptoms, including gas, gut pain, diarrhoea or constipation, severe headaches, severe fatigue, loss of cognitive functions such as concentration, memory and reasoning, muscle and joint pain, heart palpitations, and a variety of allergies (Matthews and Campbell, 2000; Matthews et al., 2005; Waud et al., 2008). These can be explained by the production of toxic metabolites from gut bacteria, as a result of anaerobic digestion of carbohydrates and other foods, not absorbed in the small intestine. These metabolites include alcohols, diols such as butan 2,3 diol, ketones, acids, and aldehydes such as methylglyoxal (Campbell et al., 2005, 2009). These 'toxins' induce calcium signals in bacteria and affect their growth, thereby acting to modify the balance of microflora in the gut (Campbell et al., 2004, 2007a,b). These bacterial 'toxins' also affect signalling mechanisms in cells around the body, thereby explaining the wide range of symptoms in people with food intolerance. This new mechanism also explains the most common referral to gastroenterologists, irritable bowel syndrome (IBS), and the illness that afflicted Charles Darwin for 50 years (Campbell and Matthews, 2005a,b). We propose it will lead to a new understanding of the molecular mechanism of type 2 diabetes and some cancers.

Potassium channels in hippocampal neurones are absent in a transgenic but not in a chemical model of Alzheimer's disease.

We have investigated using single channel patch-clamp methods potassium channel prevalence in hippocampal neurones from two animal models of AD. Experiments have been carried out on transgenic mice (Tg2576) carrying the Swedish mutation (K670N/M671L) and rats receiving ventricular infusions of okadaic acid. In cell-attached patches from hippocampal neurones from the Tg2576 and control littermate mice there were three principal unitary conductance - 22 pS, 111 pS and 178 pS. The two channels of intermediate and large conductance were voltage-dependent, highly active in cell-attached patches, activity decreasing markedly on hyperpolarisation. The large conductance channel was sensitive to TEA, iberiotoxin, was activated in excised inside-out patches by Ca 2+(i) and is the type I maxi-K+ channel. Significantly, there was a reduction in the prevalence of a TEA-sensitive 113 pS channel in neurones from TG2576 mice with a corresponding increase in prevalence of the maxi-K+ channel. There was no difference in the characteristics of maxi-K+ between patches in neurones from the transgenic and littermate controls. In the rat model single channel analysis was performed on hippocampal neurons from three groups of animals i.e. non-operated, and these receiving an infusion of vehicle or vehicle with okadaic acid. Three principal unitary conductances of around 18 pS, 118 pS and 185 pS were also observed in cell-attached recordings from these three groups. The intermediate and high conductance channels were blocked by TEA or 4-AP or 140 mM RbCl. There were no statistically significant differences in the channel prevalence or channel density between the control and test groups.

Characterisation of large-conductance calcium-activated potassium channels (BK(Ca)) in human NT2-N cells.

Large-conductance calcium-activated potassium (BK(Ca)) channels were studied in inside-out patches of human NTERA2 neuronal cells (NT2-N). In symmetrical (140 mM) K(+) the channel mean conductance was 265 pS, the current reversing at approximately 0 mV. It was selective (P(K)/P(Na)=20:1) and blocked by internal paxilline and TEA. The open probability-voltage relationship for BK(Ca) was fitted with a Boltzmann function, the V((1/2)) being 76.3 mV, 33.6 mV and -14.1 mV at 0.1 muM, 3.3 muM and 10 muM [Ca(2+)](i), respectively. The relationship between open probability and [Ca(2+)](i) was fitted by the Hill equation (Hill coefficient 2.7, half maximal activation at 2.0 muM [Ca(2+)](i)). Open and closed dwell time histograms were fitted by the sum of two and three voltage-dependent exponentials, respectively. Increasing [Ca(2+)](i) produced both an increase in the longer open time constant and a decrease in the longest closed time constant, so increasing mean open time. "Intracellular" ATP evoked a concentration-dependent increase in NT2-N BK(Ca) activity. At +40 mV half-maximum activation occurred at an [ATP](i) of 3 mM (30 nM [Ca(2+)](i)). ADP and GTP were less potent, and AMP-PNP was inactive. This is the first characterisation of a potassium channel in NT2-N cells showing that it is similar to the BK(Ca) channel of other preparations.

Homozygosity for a HERG potassium channel mutation causes a severe form of long QT syndrome: identification of an apparent founder mutation in the Finns.

OBJECTIVES: We studied the clinical characteristics and molecular background underlying a severe phenotype of long QT syndrome (LQTS). BACKGROUND: Mutations of cardiac ion channel genes cause LQTS, manifesting as increased risk of ventricular tachycardia and sudden death. METHODS: We studied two siblings showing prolonged QT intervals corrected for heart rate (QTc), their asymptomatic parents with only marginally prolonged QTc intervals and their family members. The potassium channel gene HERG was screened for mutations by deoxyribonucleic acid sequencing, and the electrophysiologic consequences of the mutation were studied in vitro using the whole-cell patch-clamp technique. RESULTS: A novel missense mutation (L552S) in the HERG channel, present in the homozygous state in the affected siblings and in the heterozygous state in their parents, as well as in 38 additional subjects from six LQTS families, was identified. One of the homozygous siblings had 2:1 atrioventricular block immediately after birth, and died at the age of four years after experiencing unexplained hypoglycemia. The other sibling had an episode of torsade de pointes at the age of two years. The mean QTc interval differed significantly (p < 0.001) between heterozygous symptomatic mutation carriers (500 +/- 59 ms), asymptomatic mutation carriers (452 +/- 34 ms) and noncarriers (412 +/- 23 ms). When expressed in vitro, the HERG-L552S formed functional channels with increased activation and deactivation rates. CONCLUSIONS: Our data demonstrate that homozygosity for a HERG mutation can cause a severe cardiac repolarization disorder without other phenotypic abnormalities. Absence of functional HERG channels appears to be one cause for intrauterine and neonatal bradycardia and 2:1 atrioventricular block.

High activity K+ channels in rat hippocampal neurones maintained in culture.

A channel was identified in cell-attached recordings in rat hippocampal neurones maintained in culture. This channel, which was highly active at the resting membrane potential, was present in most (73 %) patches studied. The channel was characterized by long duration openings and a high open probability (Po, mean value 0.73 at -70 mV) at negative patch potentials with mild voltage dependence over the range -40 to -120 mV. It showed inward rectification. There were up to five active channels in cell-attached recordings in experiments where the cells were bathed in sodium-containing Locke solution. The single channel conductances in cell-attached recordings with 140 or 40 mM K+ in the patch pipette were 26 and 12 pS, respectively. The channel was therefore selective for K+ over Na+. The channel was not permeable to Rb+ ions. The single channel conductance was 24 pS in excised inside-out patches bathed in symmetrical K+ (140 mM) solutions. Examination of the channel kinetics revealed that both the open and closed time distributions could be fitted by the sum of three exponentials, there being no pronounced voltage sensitivity between -60 and -120 mV. The 26 pS K+ channel was insensitive to extracellular TEA, apamin, 4-AP and dequalinium. Neither was it sensitive to intracellular Ca2+. Extracellular Ba2+ was effective in reversibly blocking the channel, the IC50 being 2.0 mM. There was no obvious effect of bath application of the K+ channel opener, lemakalim, or a cAMP analogue. This channel appears to contribute a significant proportion (at least 30 %) of the resting conductance in these neurones.

In vitro patch-clamp studies in skin fibroblasts.

We have conducted single-channel patch-clamp experiments in skin fibroblasts maintained in culture. Two different cell lines, a mouse 3T3-L1 cell line and a human B17 cell line, were selected for these pilot studies. Recordings were made from both cell-attached and excised inside-out patches at room temperature. In the case of the 3T3-L1 cells, the success rate in obtaining good seals (> 1Gomega) was low, and channel openings in either cell-attached or excised patches were rare. We have, however, identified a channel in a cell-attached configuration with a slope conductance of 39 pS in symmetrical K+ solutions. In the case of the human B17 cells, good quality seals were more readily obtained. One principal type of channel opening was identified. In cell-attached patches, the prevalent type of channel in symmetrical K+ solutions had a conductance of 187 pS. This channel was activated by strong depolarization, and there was usually more than one active channel in the patch. It was blocked by extracellular tetraethylammonium (20 mM), and persisted when external Cl- was replaced by aspartate. In excised inside-out patches bathed in symmetrical K+, this channel was activated by an increase in Ca+ applied to the intracellular face. A large conductance channel (175 pS) was also observed in excised inside-out patches, with a reverse physiological K+ gradient. This channel had a reversal potential > 40 mV and appeared not to be voltage-dependent under these recording conditions (2 mM Ca(2+)i). We conclude that the channel we have identified in these cells belongs to the maxi-K+ channel class.

Effects of high helium pressure on intracellular and field potential responses in the CA1 region of the in vitro rat hippocampus.

We have investigated the effects of high helium pressure (up to 13.3 MPa) on the electrophysiological responses of CA1 neurons in rat hippocampal slices using a purpose built pressure chamber, designed to facilitate field potential and intracellular recording. In field potential experiments, near threshold orthodromic responses were depressed by modest pressure (0.4 MPa). At higher stimulus intensities, orthodromic and antidromic population spike amplitudes were not increased at 5 MPa but were significantly enhanced at 10 MPa, and multiple population spikes were observed in some experiments. Orthodromic paired pulse potentiation was not affected by pressure up to 10 MPa. In intracellular experiments there were no significant differences between mean values obtained for resting membrane potential and input resistance at atmospheric pressure and pressures of up to 10 MPa. However, spontaneous depolarizing membrane potential excursions, decreased slow after-hyperpolarization responses and reduced accommodation properties were observed at pressure (5-10 MPa). One possibility is that the SK and M potassium channel systems may be more sensitive to high pressure than other membrane ion channels. These effects may contribute towards the high pressure neurological syndrome observed in vivo.

Properties of single calcium-activated potassium channels of large conductance in rat hippocampal neurons in culture.

Patch-clamp recordings were made on rat hippocampal neurons maintained in culture. In cell-attached and excised inside-out and outside-out patches a large single-channel current was observed. This channel had a conductance of 220 and 100 pS in 140 mM [K+]i/140 mM [K+]o and 140 mM [K+]i/3 mM [K+]o respectively. From the reversal potential the channel was highly selective for K+, the PK+/PNa+ ratio being 50/1. Channel activity was voltage-dependent, the open probability at 100 nM [Ca2+]i increasing by e-fold for a 22 mV depolarization. It was also dependent on [Ca2+]i at both resting and depolarized membrane potentials. Channel open states were best described by the sum of two exponentials with time constants that increased as the membrane potential became more positive. Channel activity was sensitive to both external (500 microM) and internal (5 mM) tetraethylammonium chloride. These data are consistent with the properties of maxi-K+ channels described in other preparations, and further suggest a role for maxi-channel activity in regulating neuronal excitability at the resting membrane potential. Channel activity was not altered by 8-chlorophenyl thio cAMP, concanavalin A, pH reduction or neuraminidase. In two of five patches lemakalim (BRL 38227) increased channel activity. Internal ruthenium red (10 microM) blocked the channel by shortening the duration of both open states. This change in channel gating was distinct from the 'mode switching' seen in two patches, where a channel switched spontaneously from normal activity typified by two open states to a mode where only short openings were represented.

The action of anaesthetics and high pressure on neuronal discharge patterns.

1. The membrane actions of both anaesthetics and high pressure have been studied in rat hippocampal slices in experiments where either field potential (orthodromic or antidromic) responses from the CA1 region are recorded or intracellular measurements in CA1 neurones are made. 2. It is clear that anaesthetics have multiple post-synaptic actions in CA1 pyramidal neurones. For example, the amplitude of antidromic field potential responses are depressed (e.g. 2.5% enflurane) or increased (20 mM ketamine) or recruitment of a second population spike occurs (2.5% halothane). 3. In separate intracellular experiments anaesthetics have been shown to hyperpolarize [e.g. inhalations (2.5%), or methohexitone, 50-100 microM), or depolarize (ketamine, > or = 20 microM), CA1 pyramidal neurones decreasing or increasing respectively the responses to weak depolarizing synaptic input, or direct stimulation. 4. In the case of some anaesthetics (inhalation agents or ketamine), the accommodation of action potential discharge is also decreased, this being accompanied by a reduction in the amplitude of the associated slow after hyperpolarization (AHP). Consequently many neurones fire repetitively in response to long lasting, strong depolarizing inputs. Sub-classes of K+ channel such as the M (channel closed by muscarinic agonists) and the SK (Ca(2+)-dependent K+ channel of small conductance) type are currently believed to control the accommodation of spike discharge and the AHP. Consistent with this idea is the finding that in voltage-clamp experiments enflurane decreased reversibly the M current. 5. Methohexitone (50 microM) does not block the accommodation of action potential discharge but interestingly induces a long lasting depolarization and action potential bursting. 6. In comparison, high pressure (51-101 ATA) can induce a second population spike in antidromic field potential recordings, indicative also of a post-synaptic action. 7. There is no apparent change in the resting membrane potential or input resistance of CA1 neurones at high pressure, however 51 or 101 ATA produced a reduction in the accommodation of action potential discharge and the associated AHP leading to repetitive discharge in response to strong (0.7 nA) depolarizing currents. 8. In a few neurones spontaneous depolarizations and action potential discharge also occurred during compression between 51-101 ATA. 9. Our working hypothesis is that certain subclasses of neuronal K+ channel represent interesting targets for both anaesthetic and high pressure action.

Effects of four drugs on 4-aminopyridine seizures: a comparison with their effects on HPNS.

The effects of two i.v. anesthetics, Saffan and methohexitone (MHX) and two N-methyl-D-aspartate receptor antagonists, MK-801 (Dizocilpine) and 2-aminophosphonoheptanoate (AP7), were tested for activity against the motor excitation (tremor, whole body jerks, and seizures) produced by the K+ channel blocker 4-aminopyridine (4-AP). Saffan increased the dose of 4-AP required for all three endpoints; MHX had no effect on tremor but reduced the 4-AP required to produce jerks and seizures. MK-801 also reduced the 4-AP dose required to produce jerking but did not affect tremor or seizures. In contrast, AP7 increased the amount of 4-AP required to produce all endpoints. The effects of these drugs on 4-AP-induced excitation are similar to their actions on hyperbaric excitation, reported by us previously, and suggest that blockade of K+ channels may contribute to the high pressure nervous syndrome.

Methods for intracellular recording from hippocampal brain slices under high helium pressure.

A method for intracellular recording from rat hippocampal brain slices under helium pressure is described. The preparation is mounted on a horizontal mobile platform that is rolled into the pressure chamber and can be viewed at pressure. Remote manipulation of the glass microelectrodes is achieved by a high-resolution electrically driven commercially available system. The slice is superfused continuously from a closed system within the chamber. Temperature is maintained at 37 degrees C and PO2 at 0.5 atm within the pressure chamber. A pressure of 200 ATA can be obtained, although thus far recordings have been made up to only 130 ATA. The experiments demand that a number of sample recordings be made from the same slice at both ambient and high pressure, and tests have proved that, although difficult, this can be achieved. The resting membrane potential, the current-voltage relationship, and the action potential responses to short (8 ms), medium (80 ms), and long (800 ms) depolarizing current pulses have all been measured in CA1 pyramidal neurons.

Exposure to high pressure may produce the 5-HT behavioral syndrome in rats.

In addition to the motor events associated with high pressure neurologic syndrome (HPNS), we have observed behavioral changes that resemble the 5-hydroxytryptamine (5-HT) syndrome in free-moving rats exposed to pressures up to 70 ATA. These include a flat body posture, head weaving, reciprocal forepaw treading, and hyperlocomotion. Such changes occur when brain 5-HT levels are raised or when 5-HT receptors are activated. We have therefore studied the behavior of rats at pressure treated either with saline or with one of the following drugs: p-chlorophenylalanine (pCPA) which depletes brain 5-HT by 85-90%, Wy 27587 which inhibits 5-HT reuptake, 5-hydroxytryptophan (5-HTP) and carbidopa which increase brain 5-HT synthesis, and quipazine which is a 5-HT receptor-agonist. After treatment, rats were individually exposed to pressure, and behavioral scores were made for 5 min every 10 ATA up to 70 ATA by an unbiased observer who was not aware of the treatment given. Analysis of all control rats indicated that only a flat body posture, forepaw treading, and hyperlocomotion were positively correlated with pressure, and these events were used in all subsequent analysis. Rats treated with pCPA with whole brain 5-HT levels reduced by 90% had scores significantly less than controls. Rats treated with Wy 27587 showed significantly increased scores. Rats treated with 5-HTP and quipazine failed to show a significant increase in scores. These results suggest that a modified form of the 5-HT syndrome occurs when rats are exposed to increased pressure, and the behavioral events seen are consistent with some activation of the 5-HT1A receptor subtype.

Inhalation anaesthetics block accommodation of pyramidal cell discharge in the rat hippocampus.

The effects of the three inhalation anaesthetics enflurane, isoflurane and halothane were tested in vitro on accommodation of rat CA1 neurones. At near clinical concentrations (approximately 2.5%) the anaesthetics slightly depressed antidromic field potential responses. At the same concentrations the anaesthetics also blocked accommodation reversibly and reduced the after hyperpolarization of CA1 neurones. No significant changes in the threshold potential were observed, although the resting membrane potential was often increased in the presence of the anaesthetics. The action of enflurane was not blocked by propranolol 20 mumol litre-1 and enflurane had no obvious effect on the duration of Ca2+ spikes of CA1 neurones. It is concluded that the anaesthetics may have a direct effect on membrane K+ channels such as the Ca2+-activated K+ conductance and that the block of accommodation is unlikely to account for the proconvulsant action of enflurane.

In vitro actions of ketamine and methohexitone in the rat hippocampus.

The effects of ketamine and methohexitone have been tested in vitro on rat CA1 pyramidal neurones using conventional extracellular and intracellular recording techniques. Ketamine 20-200 mumol litre-1 predominantly increased excitability by a postsynaptic action: it enhanced the amplitude of the antidromic (field) potential response in extracellular recordings; in intracellular studies depolarized or did not change the resting membrane potential; increased intrinsic excitability (assessed by direct stimulation); and reduced accommodation properties of CA1 neurones. Methohexitone 10-100 mumol litre-1 did not affect the amplitude of the antidromic field potential responses, tended to hyperpolarize and reduce the intrinsic excitability, but did not alter accommodation properties. At these concentrations these agents either did not affect or, in the case of ketamine, enhanced excitatory synaptic transmission on to the CA1 pyramidal neurones. Methohexitone 50 and 100 mumol litre-1 also induced a large, slow (several seconds) after depolarization which followed the conventional orthodromic response and may lead to action potential discharge. It is clear that these agents have multiple actions on CA1 pyramidal neurones in vitro and that ketamine and methohexitone in vitro influence excitability by different mechanisms.

The effects of non-competitive NMDA receptor antagonists on rats exposed to hyperbaric pressure.

The high pressure neurological syndrome (HPNS) occurs when man or animals are exposed to hyperbaric pressure. Four non-competitive N-methyl-D-aspartate (NMDA) antagonists - MK-801, phencyclidine (PCP), SKF 10,047 and ketamine were tested in rats for effects on the HPNS. All drugs were injected i.p. prior to compression; ketamine was also infused i.v. Control rats received saline. Rats were exposed individually to increasing helium pressure (PO2 0.5 atmospheres absolute ATA). Three endpoints were used to assess HPNS: onset pressures for tremor, myoclonus and convulsions. Neither MK-801 (0.03 and 0.3 mg/kg) nor SKF 10,047 (50 mg/kg) had any effect on the onset pressures for tremor, myoclonus or convulsions, although the type of seizure was modified from the clonic/tonic seizure seen in controls to purely clonic. PCP (5 mg/kg) had no effect on the endpoints, but pressure enhanced the excitation and stereotypy seen at 1 ATA. Ketamine (100 mg/kg i.p.) did not affect tremor or myoclonus; ketamine infused i.v. at pressure only prevented tremor and myoclonus at 'anaesthetizing' concentrations. Our results show that these non-competitive NMDA antagonists had little effect on HPNS, in contrast to competitive NMDA antagonists, such as AP7, which are highly effective. Possible explanations for this lack of effect include (1) interactions with NMDA receptor channels are pressure dependent; (2) other actions of these antagonists override their effects on the NMDA receptor channel.

The action of GABA receptor agonists and antagonists on muscle membrane conductance in Schistocerca gregaria.

1. The properties of postsynaptic gamma-aminobutyric acid (GABA) receptors in the extensor tibiae muscle of Schistocerca gregaria were studied by conventional electrophysiological recording techniques. 2. GABA and other active GABA receptor agonists produced rapid, dose-dependent, reversible increases in membrane conductance. 3. In two microelectrode experiments the ED50 for GABA was approximately 1 mM. In three microelectrode experiments (assuming short cable theory conditions) the ED50 for GABA was 2.3 mM. The Hill coefficient for GABA estimated from the latter experiments was 1.4. 4. The relative potency of muscimol/GABA at the ED50 for GABA was 1.36. 3-Aminopropane sulphonic acid (3-APS) and isonipecotic acid were weakly active, baclofen and piperidine-4-sulphonic acid (P4S) were inactive. Isoguvacine produced depolarizations and increases in conductance in preparations which hyperpolarized in response to GABA. These depolarizations were enhanced by both picrotoxin and pitrazepin although the increases in input conductance were depressed. 5. Picrotoxin (20 microM), (+)-bicuculline (20-100 microM) and pitrazepin (1-10 microM) all reversibly antagonized GABA-induced responses. Such antagonism was not competitive in the case of picrotoxin and (+)-bicuculline but was competitive for pitrazepin. Schild plot analysis gave an average pA2 value of 5.5 for pitrazepin. 6. The significance of these results is briefly discussed.