CMOS-compatible, piezo-optomechanically tunable photonics for visible wavelengths and cryogenic temperatures

We demonstrate a platform for phase and amplitude modulation in silicon nitride photonic integrated circuits via piezo-optomechanical coupling using tightly mechanically coupled aluminum nitride actuators. The platform, fabricated in a CMOS foundry, enables scalable active photonic integrated circuits for visible wavelengths, and the piezoelectric actuation functions without performance degradation down to cryogenic temperatures. As an example of the potential of the platform, we demonstrate a compact (∼40 µm diameter) silicon nitride ring resonator modulator operating at 780 nm with intrinsic quality factors in excess of 1.5 million, >10 dB change in extinction ratio with 2 V applied, a switching time less than 4 ns, and a switching energy of 0.5 pJ/bit. We characterize the exemplary device at room temperature and 7 K. At 7 K, the device obtains a resistance of approximately 20 teraohms, allowing it to operate with sub-picowatt electrical power dissipation. We further demonstrate a Mach-Zehnder modulator constructed in the same platform with piezoelectrically tunable phase shifting arms, with 750 ns switching time constant and 20 nW steady-state power dissipation at room temperature.

Calcium dependence of the inactivation of calcium currents in skeletal muscle fibers of an insect

Calcium currents in skeletal muscle fibers of an insect, Carausius morosus, inactivate under depolarization. This inactivation depends on the current being carried across the membrane by calcium ions, rather than strontium or bariumions.

The response of the tandem pore potassium channel TASK-3 (K(2P)9.1) to voltage: gating at the cytoplasmic mouth

Although the tandem pore potassium channel TASK-3 is thought to open and shut at its selectivity filter in response to changes of extracellular pH, it is currently unknown whether the channel also shows gating at its inner, cytoplasmic mouth through movements of membrane helices M2 and M4. We used two electrode voltage clamp and single channel recording to show that TASK-3 responds to voltage in a way that reveals such gating. In wild-type channels, P(open) was very low at negative voltages, but increased with depolarisation. The effect of voltage was relatively weak and the gating charge small, 0.17. Mutants A237T (in M4) and N133A (in M2) increased P(open) at a given voltage, increasing mean open time and the number of openings per burst. In addition, the relationship between P(open) and voltage was shifted to less positive voltages. Mutation of putative hinge glycines (G117A, G231A), residues that are conserved throughout the tandem pore channel family, reduced P(open) at a given voltage, shifting the relationship with voltage to a more positive potential range. None of these mutants substantially affected the response of the channel to extracellular acidification. We have used the results from single channel recording to develop a simple kinetic model to show how gating occurs through two classes of conformation change, with two routes out of the open state, as expected if gating occurs both at the selectivity filter and at its cytoplasmic mouth.

The selectivity, voltage-dependence and acid sensitivity of the tandem pore potassium channel TASK-1: contributions of the pore domains

We have investigated the contribution to ionic selectivity of residues in the selectivity filter and pore helices of the P1 and P2 domains in the acid sensitive potassium channel TASK-1. We used site directed mutagenesis and electrophysiological studies, assisted by structural models built through computational methods. We have measured selectivity in channels expressed in Xenopus oocytes, using voltage clamp to measure shifts in reversal potential and current amplitudes when Rb+ or Na+ replaced extracellular K+. Both P1 and P2 contribute to selectivity, and most mutations, including mutation of residues in the triplets GYG and GFG in P1 and P2, made channels non-selective. We interpret the effects of these--and of other mutations--in terms of the way the pore is likely to be stabilised structurally. We show also that residues in the outer pore mouth contribute to selectivity in TASK-1. Mutations resulting in loss of selectivity (e.g. I94S, G95A) were associated with slowing of the response of channels to depolarisation. More important physiologically, pH sensitivity is also lost or altered by such mutations. Mutations that retained selectivity (e.g. I94L, I94V) also retained their response to acidification. It is likely that responses both to voltage and pH changes involve gating at the selectivity filter.

The selectivity filter of the tandem pore potassium channel TASK-1 and its pH-sensitivity and ionic selectivity

We have studied pH sensitivity and ionic selectivity of the tandem pore K(+) channel TASK-1 heterologously expressed in Xenopus oocytes. We fit pH sensitivity assuming that only one of the two residues H98 need be protonated for channels to be shut. The effect of protons was weakly voltage dependent with a p K(a) of 6.02 at +40 mV. Replacement of His (H98D, H98N) reduced pH sensitivity but did not abolish it. Use of a concatameric channel permitted replacement of one His residue only; this concatamer was fully pH-sensitive. Increasing the number of His residues to 4 (mutant D204H) abolished pH sensitivity over the physiological range. The implication that D204 plays a role in pH-sensitivity was confirmed by the finding that pH sensitivity over the physiological range was also abolished in the mutant D204N. Ionic selectivity was also altered in D204H, D204N and H98D mutants. P(Rb)/ P(K) was increased from 0.80+/-0.04 (n=19) in wild type to 1.06+/-0.04 (n=19) in D204H. H98D, D204H and D204N were permeable to Na(+) with P(Na)/ P(K)=0.39+/-0.03 (n=14) in H98D, 0.64+/-0.04 (n=18) in D204H and 0.33+/-0.07 (n=3) in D204N. Thus, the arrangement of ring of residues HDHD appears to optimise both pH sensitivity and ionic selectivity.

TASK-5, a novel member of the tandem pore K+ channel family

We have cloned a novel member of the tandem pore K+ channel family from human brain cDNA. The novel cDNA encodes a 330-residue polypeptide of predicted molecular mass 36 kDa. We have named the channel TASK-5 owing to its sequence homology with TASK-1 and TASK-3. TASK-5 mRNA is expressed in pancreas, liver, kidney, lung, ovary, testis and heart. However, expression of TASK-5 in heterologous systems failed to elicit ionic currents. Removal of a putative endoplasmic reticulum retention sequence did not alter this finding and the distribution of channel proteins in HEK293 cells was similar for both TASK-1 and TASK-5. We tested whether TASK-5 could form heteromers with TASK-1. We show a mutant form of TASK-1 (H98N) to have a radically reduced sensitivity to acidification. Proton sensitivity could be rescued by injecting equimolar amounts of wild-type and mutant TASK-1 cRNA into Xenopus oocytes; the effect was that expected if half the channels formed are heteromers. Co-expression of TASK-5 with TASK-1 H98N does not affect the proton sensitivity of mutant TASK-1; thus TASK-5 appears not to form heteromers with TASK-1. Nonetheless, TASK-5 may require some other, unidentified partner subunit to form functional channels in the plasma membrane or it may form a channel in an intracellular organelle.

An improved cell isolation technique for studying intracellular Ca(2+) homeostasis in neurones of the cochlear nucleus

Neurones isolated from various parts of the brain are used extensively for electrophysiological and immuncytochemical studies, as well as to investigate their Ca(2+) homeostasis. In this work we report on an isolation technique that yielded neurones suitable for functional studies targeting the investigation of their Ca(2+) handling mechanisms. The cell isolation involved enzymatic dissociation with combined collagenase/pronase treatment and gentle mechanical trituration. At the end of the isolation the cells were incubated in a cell culture incubator (CO2 concentration = 5.1%) at 37 degrees C in Dulbecco's modified Eagle's medium (DMEM) supplemented with 10% heat-inactivated horse serum. The vitality of the isolated cells was indicated by their low intracellular Ca(2+) concentrations (17.2 +/- 0.5 nM; n = 38) and by their ability to produce large Ca(2+) transients on depolarization. These Ca(2+) transients were rapidly terminated and the resting intracellular Ca(2+) concentration was quickly restored proving that isolation did not compromise the Ca(2+) homeostatic mechanisms of the nerve cells. The technique allowed reliable, long (45-60 min) and reproducible measurements of Ca(2+) currents on these neurones as well as the recording of their intracellular Ca(2+) concentration. Our results indicate that incubation in DMEM with horse serum markedly increases the number of surviving neurones after the enzyme treatment, and their Ca(2+) homeostasis can be studied for significantly longer periods of time.

The K+ channel signature sequence of murine Kir2.1: mutations that affect microscopic gating but not ionic selectivity

1. We have studied the effects on ionic selectivity and gating of Kir2.1 of replacing Tyr (Y) in the GYG signature sequence with Phe (Y145F), Leu (Y145L), Met (Y145M), Ala (Y145A) or Val (Y145V). 2. The mutant Y145F showed no changes in ionic selectivity (as indicated by the permeability coefficient ratios PNa/PK or PRb/PK), indicating that a hydrogen bond between Tyr and other residues is not essential for K+ selectivity. Y145L, Y145M, Y145A and Y145V did not express as monomers. 3. None of the channels made from covalently linked tandem dimers with wild-type and mutant subunits (WT-mutant) had altered ionic selectivity (PNa/PK or PRb/PK), indicating that 4-fold symmetry is not required. 4. Macroscopic currents activated under hyperpolarization and the time constants for activation were reduced e-fold per 23 mV hyperpolarization in wild-type. This gating, believed to be due to the release of polyamines from the pore, was little affected by mutation of Y14. There was similarly little effect on the relationship between chord conductance (gK) and membrane potential. 5. Unitary conductance (140 mM [K+]o) was also little affected by mutation and was reduced only in channels formed from WT-Y145M, from 22.7 +/- 0.4 pS (n = 5) in wild-type to 17.1 +/- 0.5 pS (n = 4) in WT-Y145M. 6. Steady-state recording of unitary currents showed that channel open times were affected by the residue that replaced Tyr in GYG. Channel openings were particularly brief in WT-Y145V, where the mean open time was reduced from 102 ms at -120 mV in wild-type to 6 ms in WT-Y145V. 7. Thus in Kir2.1, GFG can act as a K+ selectivity filter, as can G(L/M/A/V)G, at least in dimers also containing GYG. Channel open time duration depended on the residue at position 145, consistent with the H5 region helping to determine the dwell time of the channel in the open state.

Residues beyond the selectivity filter of the K+ channel kir2.1 regulate permeation and block by external Rb+ and Cs+

1. Kir2.1 channels are blocked by Rb+ and Cs+ in a voltage-dependent manner, characteristic of many inward rectifier K+ channels. Mutation of Ser165 in the transmembrane domain M2 to Leu (S165L) abolished Rb+ blockage and lowered Cs+ blocking affinity. At negative voltages Rb+ carried large inward currents. 2. A model of the Kir2.1 channel, built by homology with the structure of the Streptomyces lividans K+ channel KcsA, suggested the existence of an intersubunit hydrogen bond between Ser165 and Thr141 in the channel pore-forming P-region that helps stabilise the structure of this region. However, mutations of Thr141 and Ser165 did not produce effects consistent with a hydrogen bond between these residues being essential for blockage. 3. An alternative alignment between the M2 regions of Kir2.1 and KcsA suggested that Ser165 is itself a pore-lining residue, more directly affecting blockage. We were able to replace Ser165 with a variety of polar and non-polar residues, consistent with this residue being pore lining. Some of these changes affected channel blockage. 4. We tested the hypothesis that Asp172 - a residue implicated in channel gating by polyamines - formed an additional selectivity filter by using the triple mutant T141A/S165L/D172N. Large Rb+ and Cs+ currents were measured in this mutant. 5. We propose that both Thr141 and Ser165 are likely to provide binding sites for monovalent blocking cations in wild-type channels. These residues lie beyond the carbonyl oxygen tunnel thought to form the channel selectivity filter, which the blocking cations must therefore traverse.

Potassium-depolarization-induced cytoplasmic [Ca2+] transient in freshly dissociated pyramidal neurones of the rat dorsal cochlear nucleus

The significance of voltage-activated Ca2+ currents in eliciting cytoplasmic Ca2+ transients was studied in pyramidal neurones isolated from the rat dorsal cochlear nucleus using combined enzyme treatment/mechanical trituration. Increases in cytoplasmic Ca2+ concentration ([Ca2+]i) were evoked by K+-induced depolarizations (10-50 mM) and monitored by the Fura-2 fluorimetric technique. The acutely dissociated neurones had a resting [Ca2+]i of 17.2+/-0.5 nM. They possessed caffeine-sensitive Ca2+ stores which were empty at rest; these stores could be filled with Ca2+ entering from the extracellular space and were re-emptied quickly. The effects of various specific high-voltage-activated (HVA) Ca2+ channel antagonists (nifedipine, omega-agatoxin IVA and omega-conotoxin GVIA) on [Ca2+]i transients were tested. Analysis of the blocking effects of these agents on the [Ca2+]i, transients indicates that, in the pyramidal neurones of the dorsal cochlear nucleus, N-type Ca2+ channels are primarily responsible for producing the depolarization-induced increases in [Ca2+]i.

Characterisation of Kir2.0 proteins in the rat cerebellum and hippocampus by polyclonal antibodies

Rabbit polyclonal antibodies were raised to rat Kir2.0 (Kir2.1, Kir2.2 and Kir2.3) inwardly rectifying potassium ion channel proteins. The antibody specificities were confirmed by immunoprecipitation of [35S]-methionine-labelled in vitro translated channel proteins and western blotting. Immunohistochemistry revealed a different patterns of expression of Kir2.0 subfamily proteins in the rat hind-brain (cerebellum and medulla) and fore-brain (hippocampus). Notably, only Kir2.2 protein was detected in the cerebellum and medulla, Kir2.1, Kir2.2 and Kir2.3 proteins were expressed in the hippocampus and immunostaining was not limited to neuronal cell types. Anti-Kir2.1 (fore-brain only) and anti-Kir2.2 (fore- and hind-brain) antibodies showed positive staining in macroglia, endothelia, ependyma and vascular smooth muscle cells. In contrast, anti-Kir2.3 (fore-brain only) immunostaining was limited to neurons, macroglia and vascular smooth muscle. These results indicate that specific regions within the rat fore- and hind-brain have differential distributions of inwardly rectifying potassium ion channel proteins.

The possible role of a disulphide bond in forming functional Kir2.1 potassium channels

The role of two cysteine residues--Cys122 and Cys154--in the structure of the strong inward rectifier K+ channel, Kir2.1, has been investigated using site-directed mutagenesis and electrophysiology. Such cysteine residues are conserved across the inward rectifier family and may be expected to form a crucial disulphide bond. Our experiments show that when the cysteines are absent, the protein is expressed, but the channels are not functional, suggesting that the disulphide bond is essential for correct channel assembly. However, reducing agents applied extracellularly have little effect on current amplitude in wild-type, so that, once the channel is assembled correctly in the membrane, the disulphide bonds are no longer essential for function. Molecular modelling suggests that a disulphide bond is formed--this may be either an intra- or an inter-subunit.

Possible modulatory role of voltage-activated Ca(2+) currents determining the membrane properties of isolated pyramidal neurones of the rat dorsal cochlear nucleus

Voltage-activated Ca(2+) currents have been studied in pyramidal cells isolated enzymatically from the dorsal cochlear nuclei of 6-11-day-old Wistar rats, using whole-cell voltage-clamp. From hyperpolarized membrane potentials, the neurones exhibited a T-type Ca(2+) current on depolarizations positive to -90 mV (the maximum occurred at about -40 mV). The magnitude of the T-current varied considerably from cell to cell (-56 to -852 pA) while its steady-state inactivation was consistent (E(50)=-88.2+/-1.7 mV, s=-6. 0+/-0.4 mV). The maximum of high-voltage activated (HVA) Ca(2+) currents was observed at about -15 mV. At a membrane potential of -10 mV the L-type Ca(2+) channel blocker nifedipine (10 microM) inhibited approximately 60% of the HVA current, the N-type channel inhibitor omega-Conotoxin GVIA (2 microM) reduced the current by 25% while the P/Q-type channel blocker omega-Agatoxin IVA (200 nM) blocked a further 10%. The presence of the N- and P/Q-type Ca(2+) channels was confirmed by immunochemical methods. The metabotropic glutamate receptor agonist (+/-)-1-aminocyclopentane-trans-1, 3-dicarboxylic acid (200 microM) depressed the HVA current in every cell studied (a block of approximately 7% on an average). The GABA(B) receptor agonist baclofen (100 microM) reversibly inhibited 25% of the HVA current. Simultaneous application of omega-Conotoxin GVIA and baclofen suggested that this inhibition could be attributed to the nearly complete blockade of the N-type channels. Possible physiological functions of the voltage-activated Ca(2+) currents reported in this work are discussed.

The dependence of Ag+ block of a potassium channel, murine kir2.1, on a cysteine residue in the selectivity filter

Externally applied Ag+ (100-200 nM) irreversibly blocked the strong inwardly rectifying K+ channel, Kir2.1. Mutation to serine of a cysteine residue at position 149 in the pore-forming H5 region of Kir2.1 abolished Ag+ blockage. To determine how many of the binding sites must be occupied by Ag+ before the channel is blocked, we measured the rate of channel block and found that our results were best fitted assuming that only one Ag+ ion need bind to eliminate channel current. We tested our hypothesis further by constructing covalently linked dimers and tetramers of Kir2.1 in which cysteine had been replaced by serine in one (dimer) or three (tetramer) of the linked subunits. When expressed, these constructs yielded functional channels with either two (dimer) or one (tetramer) cysteines per channel at position 149. Blockage in the tetramer was complete after sufficient exposure to 200 nM Ag+, a result that is also consistent with only one Ag+ being required to bind to Cys149 to block fully. The rate of development of blockage was 16 times slower than in wild-type channels; the rate was 4 times slower in channels formed from dimers.

The selectivity filter of a potassium channel, murine kir2.1, investigated using scanning cysteine mutagenesis

We have produced a structural model of the pore-forming H5 (or P) region of the strong inward rectifier K+ channel, Kir2.1, based initially on an existing molecular model of the pore region of the voltage-gated K+ channel, Kv1.3. Cysteine-scanning mutagenesis and subsequent blockage by Ag+ was used to test our model by determining the residues in H5 whose side chains line the ion conduction pathway. Mutations made in eight positions within the highly conserved H5 region resulted in apparently non-functional channels. Constructing covalently linked dimers, which carry a cysteine substitution in only one of the linked subunits, rescued six of these mutants; a covalently linked tetramer, carrying a cysteine substitution on only one of the linked subunits, rescued a further mutant. Our results using the dimers and tetramers suggest that residues Thr141, Thr142, Ile143, Tyr145, Phe147 and Cys149 are accessible to externally applied Ag+ (100-200 nM) and therefore that their side chains line the channel pore. We conclude that the topology of the Kir pore is similar, but not identical, to that of Kv channels. Additionally, the molecular model suggests that selectivity may be conferred both by aromatic residues (Tyr145 and Phe147) via cation-pi interactions and by backbone carbonyl groups (Thr142 and Gly144).

Membrane currents influencing action potential latency in granule neurons of the rat cochlear nucleus

Granule cells are the most numerous neurons in the cochlear nucleus, but, because of their small size, little information on their membrane properties and ionic currents is available. We used an in vitro slice preparation of the rat ventral cochlear nucleus to make whole-cell recordings from these cells. Under current clamp, some granule neurons fired spontaneous action potentials and all generated a train of action potentials on depolarization (threshold current, 10-35 pA). Hyperpolarization increased the latency to the first action potential evoked during a subsequent depolarization. We examined which voltage-gated currents might underlie this latency shift. In addition to a fast inward Na+ current, depolarization activated two outward potassium currents. A transient current was rapidly inactivated by membrane potentials positive to -60 mV, while a second, more slowly inactivating current was observed following the decay of the transient current. No hyperpolarization-activated conductances were observed in these cells. Modelling of the currents suggests that removal of inactivation on hyperpolarization accounts for the increased action potential latency in granule cells. Such a mechanism could account for the 'pauser'-type firing patterns of the fusiform cells which receive a prominent projection from the granule cells in the dorsal cochlear nucleus.

Activation of ATP-dependent K + currents in intact skeletal muscle fibres by reduced intracellular pH

We have used three-microelectrode voltage clamp in conjunction with the ammonium prepulse method to investigate the effects of lowered intracellular pH (pHi) on resting potassium currents of frog skeletal muscle fibres. Potassium currents were recorded in 40 mM K+, Cl(-)-free solution in response either to voltage steps or ramps. An ammonium prepulse (2 h) reduced pHi to 6.45 from a control value of 7.19. The intracellular ATP concentration, measured with high-pressure liquid chromatography (HPLC), was unchanged by this procedure. Mean outward potassium currents were larger in low pHi than in control fibres, being about twice as large at +40 mV, whereas mean inward currents were very similar in control and low-pHi fibres. The sulphonylurea glibenclamide blocked single KATP channels in excised patches with a Kd of 3 microM. In intact fibres 50 microM glibenclamide had no effect on K+ currents in controls but reduced currents in low-pHi fibres. In the presence of glibenclamide, K+ currents in low-pHi fibres were not significantly different from those in control fibres. We suggest that reduced pHi in intact skeletal muscle fibres opens ATP-dependent potassium channels (KATP channels), as has been shown to occur in excised patches of membrane.

Effect of adenosine and intracellular GTP on KATP channels of mammalian skeletal muscle

We investigated the action of adenosine and GTP on KATP channels, using inside-out patch clamp recordings from dissociated single fibers of rat flexor digitorum brevis (FDB) skeletal muscle. In excised patches, KATP channels could be activated by a combination of an extracellular adenosine agonist and intracellular Mg2+-ATP and GTP or GTP-gamma-S. The activation required hydrolyzable ATP and could be partially reversed with Mg2+, suggesting that it may involve a G-protein dependent phosphorylation of KATP channels. We found that KATP channels of the rat FDB could not be activated by Mg2+-ATP alone or by Mg2+-ATP in the presence of extracellular adenosine. Patches whose channel activity had been 'rundown' by Ca2+ could not be recovered by adenosine, GTP or Mg2+-ATP. KATP channels activated by adenosine receptor agonists had a similar ATP sensitivity to those under control conditions; but adenosine appears to be able to switch these KATP channels from an inactive to an active mode.

The role of a single aspartate residue in ionic selectivity and block of a murine inward rectifier K+ channel Kir2.1

1. The effects of Rb+ and Cs+ as blocking ions were investigated on wild-type and mutant forms of the inward rectifier K+ channel, IRK1 (Kir2.1). 2. In wild-type channels, Rb+ blockage was voltage dependent, increasing and then falling with increasing hyperpolarization. 3. Rb+ blockage was abolished by replacing Asp172 in the M2 domain of the pore-forming subunit by Asn, but was re-established by a change to Gln, narrowing the pore. Blocking affinity was reduced in D172Q, and was also reduced by replacing Gly168 in M2 by Ala. 4. Cs+ blockage was also abolished in D172N but was re-established in D172Q. 5. There appears to be a balance between charge and pore size in determining whether ions block or permeate. A major part of the selectivity of Kir2.1 is associated with Asp172 in the M2 domain.

A rate theory model for Mg2+ block of ATP-dependent potassium channels of rat skeletal muscle

1. We have studied the block by intracellular Mg2+ (0.08-4mM) of ATP-dependent potassium channels (KATP channels) from rat skeletal muscle using inside-out excised sarcolemmal patches. The block is voltage dependent, is relieved by extracellular potassium and has rapid kinetics, allowing the use of amplitude distribution analysis to estimate on and off rates. 2. To gain insight into the pore properties necessary to produce such a block, we have used an energy barrier model based on Eyring rate theory. The model has two energy wells and three barriers for K+ within the pore, while intracellular Mg2+ has access only to the inner well. We fitted the model to unitary current-voltage relations in different [Mg2+], to on and off rates, and to dissociation constants for Mg2+ block. 3. The voltage dependence of block was almost entirely due to the rate constant for unblocking. This implies that the inner energy barrier is asymmetrical, so that Mg2+ entry senses little of the voltage field, but Mg2+ exit senses about 20% of the voltage field. Best fits were obtained by placing the barrier and binding site 0.01 and 0.22, respectively, of the electrical distance through the pore from the inside. 4. The relief of block by [K+]o resulted from an increase in the unblocking rate for Mg2+, implying ionic repulsion between ions in the pore.

Protein kinase C-mediated inhibition of an inward rectifier potassium channel by substance P in nucleus basalis neurons

In nucleus basalis neurons, substance P (SP) causes a slow excitation, mediated through a pertussis toxin-insensitive G protein, by suppressing an inward rectifier K+ channel. Here we report that SP applied outside the patch pipette inhibited the single-channel activity, recorded on-cell, of the inward rectifier. The PKC inhibitors staurosporine and PKC(19-36) suppressed this effect in whole-cell mode and in on-cell single-channel mode. A diacylglycerol analog mimicked the SP effect, and PKC(19-36) suppressed this analog effect. SP irreversibly suppressed the inward rectifier in neurons treated with okadaic acid. These results indicate that a diffusible messenger mediates the SP effect, that its signal transduction involves phosphorylation by PKC, and that dephosphorylation by a serine/threonine protein phosphatase mediates its recovery.

The effect of intracellular anions on ATP-dependent potassium channels of rat skeletal muscle

1. We have used excised inside-out patches to study the effects of anions bathing the cytoplasmic surface of the membrane on ATP-dependent K+ channels of rat flexor digitorum brevis muscle. Channels were closed by ATP applied to the cytoplasmic face of the patch with a concentration for half-closure (Ki) of 14 microM, were highly selective for K+ and had unitary conductances of 62 pS in symmetrical 155 mM K+ and 27 pS in 5 mM [K+]o. 2. In 139 mM Cl- internal solution channel activity declined rapidly after excision of the patch. Inclusion of 40 mM potassium gluconate (substituted for KCl) in the solution both restored channel activity and greatly slowed its subsequent run-down. 3. The action of gluconate was concentration dependent. The effect did not involve a change in ATP binding, since the Ki for ATP was not significantly changed by gluconate, and was specific for the cytoplasmic face of the patch. 4. The anions pyruvate, lactate and acetate were all able to restore channel activity after run-down, though less well than gluconate, while sulphate and methylsulphate were without effect. 5. Analysis of single channel kinetics showed that gluconate did not affect mean open lifetime, but led to a decrease in the number and duration of long closings. 6. Anions are most likely to act by stabilizing the structure of the channel protein. Changes in the intracellular concentration of certain anions may play a role in regulating channel activity.

A single aspartate residue is involved in both intrinsic gating and blockage by Mg2+ of the inward rectifier, IRK1

1. We describe the effects on channel function of changing an aspartate residue (Asp172) in a membrane-spanning alpha-helix of the murine inward rectifier, IRK1, by site-directed mutagenesis. 2. Alteration of Asp172 to Glu (charged) or to Gln or Asn (polar but uncharged) produced functional channels showing inward rectification, though rectification was weaker with Gln and Asn. 3. Intrinsic gating around the potassium equilibrium potential, EK, was conserved only if the charge on residue 172 was conserved. Currents through channels with Gln or Asn in this position showed no time dependence under hyperpolarization. 4. The change from Asp to Gln also reduced the affinity for internal Mg2+ at least fivefold, indicating that Asp172 also forms part of the site for Mg2+ blockage. 5. The consequences for channel structure of Asp172 lining the pore are discussed.

The intrinsic gating of inward rectifier K+ channels expressed from the murine IRK1 gene depends on voltage, K+ and Mg2+

1. We describe the cloning of the inward rectifier K+ channel IRK1 from genomic DNA of mouse; the gene is intronless. 2. The IRK1 gene can be stably expressed in murine erythroleukaemia (MEL) cells. Such transfected cells show inward rectification under whole-cell recording. 3. Channels encoded by the IRK1 gene have an intrinsic gating that depends on voltage and [K+]o. Rate constants are reduced e-fold as the driving force on K+(V-EK) is reduced by 24.1 mV. 4. Removal of intracellular Mg2+ permits brief outward currents under depolarization. The instantaneous current-voltage relation may be fitted by an appropriate constant field expression. 5. Removal of intracellular Mg2+ speeds channel closure at positive voltages. In nominally zero [Mg2+]i, rate constants for the opening and closing of channels, processes which are first order, are similar to those of native channels.

Inactivating 'ball' peptide from Shaker B blocks Ca(2+)-activated but not ATP-dependent K+ channels of rat skeletal muscle

1. Shaker B inactivating 'ball' peptide is shown to produce no detectable block of ATP-dependent K+ channels of rat skeletal muscle fibres at concentrations up to 300 microM or membrane potentials up to +30 mV. 2. The peptide does produce a voltage-dependent block of large-conductance Ca(2+)-activated K+ channels at lower concentrations (K1 = 55 microM at 0 mV). An appropriate point mutation (L7E) abolishes block. 3. Mean open times, corrected for missed closures, are little affected by the blocking peptide, but burst durations are substantially reduced. 4. The inactivating peptide increases occupancy of substates, whose amplitudes are 0.27 and 0.64 of fully open.

Unitary delayed rectifier channels of rat hippocampal neurons: properties of block by external tetraethylammonium ions

Patch-clamp recording was used to characterise a delayed rectifier potassium channel and the effects of external tetraethylammonium (TEA) in neurons isolated from the CA1 region of cultured neonatal rat hippocampus. A preliminary kinetic analysis is presented. Very low concentrations of TEA included in the patch pipette solution had two effects on unitary currents: first unitary currents were reduced in amplitude, with an associated increase in open channel noise, and second channel mean open time was reduced. The reduction in unitary amplitude was consistent with a single TEA molecule blocking the channel with a voltage-independent Kd of 53.4 microM. The blocking and unblocking rate constants, estimated using two independent methods, were approximately 350 mM-1 ms-1 and 20 ms-1, both rate constants being independent of voltage. Channels blocked in this way appeared able to close normally without first having to become unblocked. The reduction in mean channel open time was probably due to a second, kinetically slower blocking reaction with a much lower Kd, probably between 300 and 800 microM. The voltage-independent blocking rate constant of the slower block was at least 25 times slower than that of the faster block.

The effect of intracellular pH on ATP-dependent potassium channels of frog skeletal muscle

1. We have used patch-clamp methods to study the effects of pH at the cytoplasmic surface of the membrane on ATP-dependent K+ channels (KATP channels) in patches excised from frog (Rana temporaria) skeletal muscle, and to study the kinetics of ATP binding. 2. In the absence of ATP, a reduction in pH led to a slight decrease in single-channel current amplitude, an increase in the number of very brief closings, an increase in the apparent mean open time, and an increase in burst duration. After correction for missed closings, the change in mean open time was slight. Despite these changes in detailed kinetics, the channel open-state probability, Popen, changed little with changes in pH in the absence of ATP. 3. In the presence of ATP, a decrease in internal pH (pHi) reduced the degree of channel inhibition by ATP, shifting the curve relating Popen and [ATP] to higher concentrations of ATP without altering its steepness. The ATP concentration for half-inhibition of channel activity (Ki) was 17 microM at pH 7.2 and 260 microM at pH 6.3. 4. The effect of pH could be modelled by assuming that one or two protons bind to the channel and prevent ATP binding to exert its effect of causing channel closure. The predicted dissociation constants for ATP and H+ respectively were 5.4 and 0.11 microM. 5. The rate constants for binding and unbinding of ATP were estimated from the dependence of the mean open time on [ATP] and from the Ki. The apparent rate constants for ATP binding were 0.6 and 0.04 mM-1 ms-1 at pH 7.2 and 6.3 respectively, while the rate constant for unbinding was 0.01 ms-1. In terms of our model the calculated true rate constant for ATP binding was 1.85 mM-1 ms-1. ATP binding also led to a reduction in burst duration. 6. The effect of pH described here differs from findings in cardiac muscle and pancreatic B-cells. The results are discussed in relation to the possible function of KATP channels in skeletal muscle during exercise.

Unitary A-currents of rat locus coeruleus neurones grown in cell culture: rectification caused by internal Mg2+ and Na+

1. We have used whole-cell and single-channel recording to study the transient outward potassium current (A-current) of rat locus coeruleus neurones grown in tissue culture. The A-current was largely inactivated at the resting potential, but could be activated from sufficiently negative holding potentials during steps positive to -50 mV. The current was sensitive to 4-aminopyridine. Another slowly activating, sustained current was similar to a delayed rectifier. 2. In the on-cell configuration the unitary conductance of channels carrying A-current was 40.9 +/- 2.2 pS (n = 6) with high external potassium (140 mM) and 14.8 +/- 1.4 pS (n = 11) with 3 mM [K+]o. The unitary current-voltage relation was not linear, but had a negative slope at very positive voltages in 3 mM [K+]o. The reversal potential changed with [K]o as expected for a K+ channel. 3. The open state probability of A-current channels was voltage dependent, reaching a peak of 0.78 +/- 0.17 (seven patches). The relationships between both activation and inactivation and membrane potential were well fitted by Boltzmann expressions. Activation was half-maximum at a potential 71.9 +/- 11.8 mV (n = 4) positive to the resting potential (approximately -61 mV). Inactivation was half-complete 29.4 +/- 3.8 mV (n = 4) negative to the resting potential. There was evidence from runs analysis for slow inactivation of channels. 4. Channels showed frequent visits to substates, the most readily identifiable of which had an amplitude 0.55 +/- 0.04 (n = 5) of the fully open state. Other substates had amplitudes of around 0.25 and 0.75. Occupancy of substates was greater at negative membrane potentials. 5. A preliminary analysis of kinetic behaviour, treating visits to substates as openings, shows that open times are distributed as a single exponential. The open time was 16.2 ms (n = 4) at a voltage 100 mV positive to the resting potential, increasing with further depolarization. Closed times are distributed as the sum of three or four exponentials. First latency distributions are strongly voltage dependent and show a delay, giving a sigmoidal rise to the distribution. Increasing temperature increased unitary current and reduced mean open time. 6. The mechanism of the rectification seen in the unitary current-voltage relationship was examined using excised, inside-out patches.(ABSTRACT TRUNCATED AT 400 WORDS)

ATP-dependent potassium channels of muscle cells: their properties, regulation, and possible functions

ATP-dependent potassium channels are present at high density in the membranes of heart, skeletal, and smooth muscle and have a low Popen at physiological [ATP]i. The unitary conductance is 15-20 pS at physiological [K+]o, and the channels are highly selective for K+. Certain sulfonylureas are specific blockers, and some K channel openers may also act through these channels. KATP channels are probably regulated through the binding of ATP, which may in turn be regulated through changes in the ADP/ATP ratio or in pHi. There is some evidence for control through G-proteins. The channels have complex kinetics, with multiple open and close states. The main effect of ATP is to increase occupancy of long-lived close states. The channels may have a role in the control of excitability and probably act as a route for K+ loss from muscle during activity. In arterial smooth muscle they may act as targets for vasodilators.

Modulation of inwardly rectifying channels by substance P in cholinergic neurones from rat brain in culture

1. Whole-cell recording was used to investigate the effects of substance P on cultured neurones from the rat nucleus basalis. 2. Brief applications of substance P produced a reduction, about 1 min in duration, of resting membrane conductance. The concentration producing a half-maximal effect was approximately 40 nM, with the continuous presence of substance P resulting in desensitization of the response. 3. The control current-voltage relation exhibited inward rectification over the voltage range -70 to -150 mV, and hyperpolarization produced a time-dependent decrease of current (inactivation). 4. The substance P-sensitive current, obtained by subtracting the current during the presence of the tachykinin from the control current, showed no time-dependent inactivation, though its current-voltage relation also revealed inward rectification, with the reversal potential being approximately equal to the potassium equilibrium potential, Vk. 5. The relation between the substance P-sensitive chord conductance and voltage could be fitted by a Boltzmann equation, with changes in [K+]o shifting this relation along the voltage axis roughly in parallel with the shift in Vk. The maximum conductance was proportional to [( K+]o). 6. Cs+ (0.1 mM) blocked the substance P-sensitive current in a voltage-dependent manner, with an equivalent valency for Cs+ of 1.9. Barium blockage of the substance P-sensitive current was less voltage dependent. 7. Replacement of external Na+ by tetramethylammonium (TMA+) ions reduced the substance P-sensitive current by only 18%. 8. These results indicate that substance P inhibits potassium channels with inward rectifier properties very similar to those of skeletal muscle. 9. Application of sodium nitroprusside did not alter the effect of substance P, suggesting that cyclic GMP plays no role in the channel modulation.

Single inwardly rectifying potassium channels in cultured muscle cells from rat and mouse

1. Inward unitary currents through inwardly rectifying K+ channels of myotubes derived from newborn rats or from a murine, clonal myoblast cell line were studied in the cell-attached configuration. Open-closed transitions of the channel were observed in the absence of blocking ions. 2. The single-channel conductance was 26.3 +/- 2.9 pS (mean + S.D., n = 14) with 150 mM-K+ pipette solution at room temperature (19-22 degrees C). The channel showed substates of conductance in addition to the main conductance state. A channel with a smaller conductance (8.9 +/- 2.6 pS, n = 4) was also but less frequently observed. 3. The probability of the channel being open is weakly voltage dependent: it decreased from 0.94 to 0.84 as the membrane was hyperpolarized from the resting potential (RP) + 20 mV to RP - 50 mV. 4. The lifetimes of the openings were distributed according to a single exponential. At least three exponentials were required to fit the frequency histogram of the lifetimes of all closed states. The mean open time showed a weak voltage dependence, while the mean closed times had little voltage dependence. 5. In the presence of external Na+, the open probability decreased from 0.89 to 0.43 and the mean open time decreased from 203 to 28 ms (40 mM-K+, 200 mM-Na+ pipette solution) when the patch membrane was hyperpolarized from RP - 40 mV to RP - 110 mV. The mean closed times were not different from those with 150 mM-K+, Na+-free pipette solution and showed little voltage dependence. 6. It is suggested that inactivation of the macroscopic inward currents during hyperpolarization results mainly from a voltage-dependent block by Na+ with relatively slow kinetics.

Multiple blocking mechanisms of ATP-sensitive potassium channels of frog skeletal muscle by tetraethylammonium ions

1. Patch-clamp methods were used to study the action of tetraethylammonium ions (TEA+) and other quaternary ammonium ions on adenosine-5'-triphosphate (ATP)-sensitive K+ channels in sarcolemmal vesicles from frog skeletal muscle. The blocking ions were applied either to the external or the internal surface of the membrane patch. 2. External TEA+ caused a very fast block, so that the amplitude of single-channel currents was reduced. Open-channel variance was decreased. The block was 1:1, with a dissociation constant (Kd) of 6-7 mM. We could detect no voltage dependence of Kd. 3. External TEA+ prolonged open times in a manner consistent with the channel being unable to close when blocked by TEA+. 4. TEA+ also blocked when applied to the internal side of the membrane. This block showed two components with different kinetics and different affinities. The slow block chopped up openings into much briefer events and had a Kd of about 1.4 mM at -3 mV. The fast block reduced the amplitude of unitary currents and was of lower affinity, with Kd around 26 mM. 5. The slow block by internal TEA+ was markedly voltage dependent, the Kd decreasing e-fold for a 37 mV depolarization. Both the association and dissociation rates were dependent on voltage. In contrast, the fast block by internal TEA+ appeared virtually independent of voltage. 6. The effects of internally applied tetramethylammonium (TMA+) and tetrapentylammonium (TPA+) ions were also investigated. Internal TMA+ produced a flickery block while the block by internal TPA+ was similar to that caused by TEA+, although TPA+ was about 10 times more effective. 7. Our results suggest that the channel has three binding sites for TEA+, one of which is accessible from the outside of the membrane. Only one of the internal sites is located so as to experience a substantial fraction of the membrane voltage field.

Rubidium ions and the gating of delayed rectifier potassium channels of frog skeletal muscle

1. Unitary currents were measured through delayed rectifier potassium channels of frog skeletal muscle, under conditions where either potassium or rubidium ions carried current. 2. Unitary currents were reduced in amplitude when Rb+ was the charge carrier, indicating that Rb+ permeated the channel less readily than did K+. On the other hand permeability ratios (PRb/PK) measured from the change in reversal potential upon ionic substitution were 0.92 for the external and 0.67 for the internal mouth of the channel. 3. Ensemble-averaged currents activated under depolarization along a similarly S-shaped time course whether K+ or Rb+ carried current, though slightly more slowly in Rb+. However, under repolarization to a negative level, tail currents were prolonged about tenfold in Rb+. 4. The duration of channel opening was substantially prolonged in Rb+. The distribution of open times was fitted by a single exponential whether K+ or Rb+ was the charge carrier, indicating a single open state. But the mean open time, averaged over all voltages investigated, was 2.65 times greater in Rb+. 5. The prolongation in Rb+ of tail currents under repolarization was associated with increases in the number of openings per burst and in the number of bursts during each tail. 6. The implications of these results for channel gating are discussed. It is argued that an early step in channel activation is more voltage dependent than later steps.

The voltage-dependent block of ATP-sensitive potassium channels of frog skeletal muscle by caesium and barium ions

1. Patch clamp techniques were used to study the action of external Cs+ and Ba2+ on adenosine 5'-triphosphate (ATP)-dependent K+ channels in sarcolemmal vesicles from frog skeletal muscle. Both ions block channels in a voltage-dependent fashion, block increasing with hyperpolarization. 2. The Cs+ block is flickery, mean unitary current being reduced and open-level noise increased. The concentration dependence is consistent with 1:1 binding, with a dissociation constant (Kd) of 4.1 mM at -62 mV. The Kd increases e-fold for a 20 mV depolarization. 3. The kinetics of Cs+ block were analysed by amplitude distribution analysis, and by measurement of the excess open-level variance. Both methods gave similar rate constants for blocking and unblocking; about 20 mM-1 ms-1 and 75 ms-1 at -62 mV. 4. All the voltage dependence of the Cs+ block appears to lie in the blocking reaction; unblocking is independent of voltage. 5. Ba2+ blocks with slower kinetics, so that blocking events can be resolved in single-channel records. Ba2+ reduces mean open time and causes long closings. 6. The blocking rate constant for Ba2+ was measured from the open times. It was about 1.7 mM-1 ms-1 at -62 mV and increased e-fold for a 40 mV hyperpolarization. The unblocking rate, measured from closed times, yielded a Kd of about 0.1 mM at -62 mV, in agreement with that measured from the reduction in open-state probability. 7. Our results suggest that Cs+ and Ba2+ block at sites within the channel, and provide evidence that the channel is a multi-ion pore.

The action of external tetraethylammonium ions on unitary delayed rectifier potassium channels of frog skeletal muscle

1. We have used single-channel recording to investigate the block by extracellular tetraethylammonium ions (TEA+) of delayed rectifier potassium channels of frog skeletal sarcolemma. 2. TEA+ blocks by reducing the apparent amplitude of unitary currents, without detectable increase in open-level current variance. 3. The block by TEA+ appeared to be 1:1, the fractional current being halved at 5.8 mM and -3 mV. The dissociation constant for the block was voltage dependent, increasing e-fold for a 138 mV depolarization. 4. Activation of delayed rectifier potassium currents is not altered by TEA+. 5. Open times, which in the presence of TEA+ represents bursts of open and blocked events, are not increased by TEA+, indicating that blocked channels are able to close normally.

Studies of the unitary properties of adenosine-5'-triphosphate-regulated potassium channels of frog skeletal muscle

1. Patch-clamp techniques were used to study adenosine-5'-triphosphate (ATP)-dependent K+ channels in sarcolemmal vesicles from frog skeletal muscle. In addition to its ATP dependence, opening of these channels was voltage dependent, the open-state probability (P open) increasing with depolarization. 2. The reversal potential of unitary currents changed with external K+ concentration, [K+]o, as expected if the Na-K permeability ration (pNa/pK) equals 0.015. Unitary conductance increased with increasing [K+]o from 14.8 +/- 0.5 pS (n = 5) in 2.5 mM-K+ to 42.3 +/- 1.0 pS (n = 8) in 60 mM-K+. This increase was less than that expected from independence. 3. Replacement of 60 mM-external K+ by 60 mM-external Rb+ shifted the reversal potential of unitary currents by -6.7 mV, suggesting that Rb+ enters channels nearly as easily as does K+ (Rb-K permeability ration, pRb/pK = 0.76). Unitary currents were much smaller in Rb+, consistent with Rb+ binding within the channel. 4. The ATP-regulated K+ channel was blocked by both internal and external tetraethylammonium ions (TEA+). 2 mM-TEA+, applied to the cytoplasmic face of membrane patches, interrupted channel openings. Higher concentrations reduced unitary current amplitude, suggesting an increase in the rapidity of TEA+ block. 5. The reduction in P open by ATP was consistent with 1:1 binding and a dissociation constant of 0.135 mM. ATP appeared not to be hydrolysed to close channels. Adenosine 5'-diphosphate (ADP) and adenosine 5'-monophosphate (AMP) were less effective than ATP, but retained channel closing properties. Substitution of adenine with other purines or with pyrimidine bases substantially reduced activity, as did substitution of ribose by 2'-deoxyribose or by ribose 2',3'-dialdehyde. 6. Sarcoplasmic Ca2+ did not influence P open. 7. Myotubes, grown from thigh muscles of new-born rats, appeared to lack ATP-dependent K+ channels. Adult frog muscle appeared to lack high-conductance Ca2+-dependent K+ channels, at least in the surface membrane. Such channels were found in myotube membranes. 8. Open- and closed-time histograms were constructed and were consistent with at least two open and at least three closed states. Channel openings were grouped in bursts. Open times, burst lengths and the number of openings per burst were reduced by ATP. 9. The effects of [K+]o on unitary conductance and of K+ replacement with Rb+ are discussed in terms of a simple Eyring rate theory formulation.(ABSTRACT TRUNCATED AT 400 WORDS)

Properties of single potassium channels in vesicles formed from the sarcolemma of frog skeletal muscle

The patch-clamp method was used to study unitary delayed rectifier K+ channels in large vesicles formed from the membrane of frog skeletal muscle. Channels were activated by depolarizing pulses. Single-channel conductance was about 15 pS in physiological [K+]o and was doubled by raising [K+]o to 120 mM. TEA+ caused an apparent reduction in single-channel current, which we attribute to a rapid block. When depolarizations were repeated at brief intervals, records with and without channel openings were ordered non-randomly, providing evidence for a slow process which was probably inactivation. In multichannel patches the relation between variance and mean current, binomial analysis, and the distribution of times for single and double openings were all consistent with channels behaving independently. Open times were distributed exponentially. Mean open time, tau o, increased with depolarization so that 1/tau o was an exponential function of voltage. First latency histograms peaked at times later than zero and could not be fitted by a scheme having only two closed states. Channel openings occurred in bursts and closed time histograms could be fitted by the sum of three exponentials. Our results imply a scheme with at least three closed states, an open and an inactivated state.

Substance P raises neuronal membrane excitability by reducing inward rectification

Much interest has recently centred on the properties of peptides that modulate the excitability of nerve cells. Such compounds include the undecapeptide substance P, which is particularly well established as an excitatory neurotransmitter, and we examine here its effects on magnocellular cholinergic neurones taken from the medial and ventral aspects of the globus pallidus of newborn rats and grown in dissociated culture. These neurones have previously been shown to respond to substance P3 and are analogous to the nucleus basalis of Meynert in man, which gives a diffuse projection to the cerebral cortex and whose degeneration is the likely cause of Alzheimer's disease. Substance P depolarizes these cultured neurones by reducing an inwardly rectifying potassium conductances; this conductance has been found in several neuronal types and has similar properties to those of certain other cells. As discussed below, modulation of inward (or anomalous) rectification by substance P implies a self-reinforcing element to the depolarization caused by the peptide.

A new preparation for recording single-channel currents from skeletal muscle

Spherical vesicles of sarcolemma (media diameter, 78 microns) were prepared from frog skeletal muscle by prolonged exposure to enzymes (collagenase, then protease) and to isotonic KCl solutions, which promote swelling of muscle fibres. Patch clamp recording was used to measure unitary K and Na currents from this preparation. Na and K channels had conductances around 15 pS and their kinetic properties appeared unaltered by vesicle formation.