The ultrastructure of patch-clamped membranes: a study using high voltage electron microscopy

Functional linkage of the cardiac ATP-sensitive K+ channel to the actin cytoskeleton

The role of the cytoskeleton in the rundown and reactivation of adenosine triphosphate (ATP) sensitive K+ channels (KATP channels) was examined by perturbing selectively the intracellular surface of inside-out membrane patches excised from guinea-pig ventricular myocytes. Actin filament-depolymerizing agents (cytochalasins and desoxyribonuclease I) accelerated channel rundown, while actin filament stabilizer (phalloidin) or phosphatidylinositol biphosphate (PIP2; inhibitor of F-actin-severing proteins) inhibited spontaneous and/or Ca2+-induced rundown. When rundown was induced by cytochalasin D or by long exposure to high Ca2+, channel activity could not be restored by exposure to MgATP, but application of F-actin with MgATP could reinstitute channel activity. The processes of rundown and reactivation of cardiac KATP channels may thus be influenced by the assembly and disassembly of the actin cytoskeletal network, which provides a novel regulatory mechanism of this channel.

Xenopus laevis oocytes contain endogenous large conductance Ca2(+)-activated K+ channels

Xenopus laevis oocytes have become a pre-eminent tool for studying cloned ion channels, primarily because they intrinsically express low levels of most types of ion channels. However, when these cells are used for single channel studies, it is essential to determine whether or not oocytes contain even low levels of endogenous ion channels with properties similar to the channel being investigated. We show here that X. laevis oocytes express endogenous large-conductance Ca2(+)-activated K+ channels with properties similar to mammalian isoforms of this channel. The endogenous channels exhibit a voltage-dependence of 12-14 mV per e-fold change in open probability (po), can be activated by micromolar Ca2+ concentrations, and have a single channel conductance of approximately 200 pS in symmetrical 110 mM K+ solutions. Patch clamp experiments indicate that this endogenous channel is present at low densities (approximately 1 channel/3000 microns2). If endogenous channel subunits can form functional tetramers with other exogenous potassium channel subunits, then they will give rise to the expression of a heterogeneous channel population. Therefore, studies involving the heterologous expression of large-conductance Ca2(+)-activated K+ channels in Xenopus laevis oocytes require careful analysis and interpretation.

The roles of Ca2+ and plasma membrane ion channels in hyphal tip growth of Neurospora crassa

Growing hyphae of the ascomycete fungus Neurospora crassa contained a tip-high gradient of cytoplasmic Ca2+, which was absent in non-growing hyphae and was insensitive to Gd3+ in the medium. Patch clamp recordings in the cell-attached mode, from the plasma membrane of these hyphae, showed two types of channel activities; spontaneous and stretch activated. The spontaneous channels were identified as inward K+ channels based on inhibition by tetraethylammonium. The stretch activated channels had increased amplitudes in response to elevated Ca2+ in the pipette solution, and thus are permeable to Ca2+ and mediate inward Ca2+ movement. Gd3+, which is an inhibitor of some stretch activated channels, incompletely inhibited stretch activated channel activity. Both tetraethylammonium and Gd3+ only transiently reduced the rates of tip growth without changing tip morphology, thus indicating that the channels are not absolutely essential for tip growth. Furthermore, in contrast to the hyphae of another tip growing organism, Saprolegnia ferax, tip-high gradients of neither spontaneous nor stretch activated channels were found. Voltage clamping of the apical plasma membrane potential in the range from -300 to +150 mV did not affect the rates of hyphal elongation. Collectively, these data suggest that ion transport across the plasma membrane at the growing tip in Neurospora is not obligatory for the maintenance of tip growth, but that a gradient of Ca2+, possibly generated from internal stores in an unknown way, is required.

The desensitization of the embryonic mouse muscle acetylcholine receptor depends on the cellular environment

The rate of desensitization of nicotinic acetylcholine (ACh) receptor (nAChR), an important characteristic of nAChR function, was studied in myotubes of the mouse C2C12 cell line at different times after fusion, by measuring the decay of ACh-evoked currents (IACh) under various patch-clamp configurations. We observed a progressive slowing of IACh decay rate (half-decay time rose from about 0.5 s to over 5 s) in myotubes of increasing size (i.e. age) under all experimental conditions, except in outside-out patches, when IACh decayed as fast as in the smallest myotubes. Single-channel conductance (about 35 pS) and open time (about 3.5 ms), measured in outside-out and cell-attached patches, were independent of myotube size. In Xenopus oocytes injected with poly(A+)RNA extracted from C2C12 myoblasts or mature myotubes, IACh decay was about 50 times slower than in myotubes. Neither cAMP-dependent nor diacylglycerol-dependent protein kinases, actin nor microtubule polymerization state influenced IACh decay. Our data indicate that the cellular environment, but not readily dialysable cytosolic factors, markedly influences the functional behaviour of nAChR.

Methods for studying neurotransmitter transduction mechanisms

This review describes the methodologies used to study the transduction mechanisms that are activated in excitable cells by G-protein-coupled agonists. In view of the complexity of second-messenger systems, it is no longer relevant to ask, "What is the transduction mechanism involved in the action of a given neuromodulator?" because, in many cases, a variety of transduction mechanisms and physiological responses are invoked following receptor activation. This means that a single aspect of the physiological response must be selected for study in order to address the question of transduction mechanism. This review is therefore concerned with a description the use of patch- and voltage-clamp procedures to study transduction mechanism because they are designed to isolate one aspect of the physiological response: the change in activity of a single type of membrane ion channel.

Cloning, expression, and distribution of functionally distinct Ca(2+)-activated K+ channel isoforms from human brain

We have cloned and expressed nine Ca(2+)-activated K+ channel isoforms from human brain. The open reading frames encode proteins ranging from 1154 to 1195 amino acids, and all possess significant identity with the slowpoke gene products in Drosophila and mouse. All isoforms are generated by alternative RNA splicing of a single gene on chromosome 10 at band q22.3 (hslo). RNA splicing occurs at four sites located in the carboxy-terminal portion of the protein and gives rise to at least nine ion channel constructs (hbr1-hbr9). hslo mRNA is expressed abundantly in human brain, and individual isoforms show unique expression patterns. Expression of hslo mRNA in Xenopus oocytes produces robust voltage and Ca(2+)-activated K+ currents. Splice variants differ significantly in their Ca2+ sensitivity, suggesting a broad functional role for these channels in the regulation of neuronal excitability.

Elimination of rapid potassium channel inactivation by phosphorylation of the inactivation gate

The effect of protein kinase C (PKC) on rapid N-type inactivation of K+ channels has not been reported previously. We found that PKC specifically eliminates rapid inactivation of a cloned human A-type K+ channel (hKv3.4), converting this channel from a rapidly inactivating A type to a noninactivating delayed rectifier type. Biochemical analysis showed that the N-terminal domain of hKv3.4 is phosphorylated in vitro by PKC, and mutagenesis experiments revealed that two serines within the inactivation gate at the N-terminus are sites of direct PKC action. Moreover, mutating one of these serines to aspartic acid mimics the action of PKC. Serine phosphorylation may thus prevent rapid inactivation by shielding basic residues known to be critical to the function of the inactivation gate. The regulatory mechanism reported here may have substantial effects on signal coding in the nervous system.

Effects of muscarine on K(+)-channel currents in the C-cells of bullfrog sympathetic ganglion

The effects of muscarine on small, putative C-cells and large, putative B-cells dissociated from bullfrog paravertebral sympathetic ganglia were studied by whole cell and single channel recording techniques. The dominant action of muscarine was to activate an inwardly-rectifying K+ current (IK(G)) in C-cells and to suppress M-current (IM) in B-cells. However, both IM and IK(G) were affected by muscarine in 5 out of 78 putative C-cells and in 8 others only IM was affected. By contrast, IK(G) was only activated in 1 out of 105 B-cells. This predicts that the muscarinic slow IPSP, which can be evoked by preganglionic stimulation, occurs exclusively in C-cells. 6% of these cells could, however, generate a muscarinic slow EPSP in addition to a slow IPSP and 10% could generate a slow EPSP without a slow IPSP. The rectification associated with IK(G) was neither a direct consequence of the direction of movement of K+ ions nor a simple consequence of channel block by intracellular Mg2+ or Na+ ions. The fit of the activation curve by a Boltzmann equation suggests that the conductance underlying IK(G) is controlled by a voltage-dependent gating charge (valency approximately -2). Muscarine activated no new channels in outside-out or cell-attached patches but increased the opening probability of two types of K+ channels (unitary conductances approximately 20 pS and approximately 55 pS). The possible role of these channels in the generation of IK(G) is discussed.

ATP is not required for anion current activated by cell swelling in multidrug-resistant lung cancer cells

During whole cell recording with 4 mM ATP and 0.1 mM GTP in the pipette, outwardly rectifying Cl- currents (155 +/- 20.5 pA/pF) were repetitively activated on reduction of bath solution osmolarity from 290 mosM (control) to 210 mosM. These currents were sensitive to 0.1-1 mM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid. Omission of ATP from the pipette solution reduced the current magnitude to 42.7 +/- 9.5 pA/pF and prevented repetitive activation. More hyposmotic solutions (160 mosM) usually elicited current repetitively despite an ATP-free pipette solution. In cells depleted of ATP (to < 5% of control) by preincubation with 2-deoxyglucose (10 mM) and rotenone (100 nM), hyposmotic solutions failed to activate significant current. Cell volume increased to 230 +/- 18% of control (19.1 +/- 1.2 microns) in 210 mosM bath (normal cells) but only to 114 +/- 13% of control in ATP-depleted cells exposed to 160 mosM solution. This failure of ATP-depleted cells to swell in hypotonic external solutions was reversed by overnight pretreatment with cytochalasin D (2 micrograms/ml; n = 6) but not by colchicine (250 microM; n = 8). In outside-out patches of membrane dialyzed with zero ATP and excised from swollen cells, we observed sustained activation of a 53-pS outwardly rectifying channel (chord conductance, +100 mV; open probability approximately 1.0). In cell-attached patches from normal and ATP-depleted cells, we activated similar channels by suction. ATP does not appear to be an absolute requirement for the activation of this Cl- channel in H69AR cells but may be essential for the normal volume response and channel activation mediated through cytoskeletal elements within cells.

Reevaluation of Ca2+ channel types and their modulation in bullfrog sympathetic neurons

With 90 mM Ba2+, the main Ca2+ current in frog sympathetic neurons peaks near +30 mV and is blocked by omega-conotoxin GVIA (omega-CgTx). It is modulated by norepinephrine (NE) in a voltage-dependent manner via a membrane-delimited mechanism. Surprisingly, a different current dominates at more negative voltages (-30 to +10 mV). That novel current is not sensitive to selective blockers of L- or N-type channels (respectively, dihydropyridines or omega-CgTx) and is inhibited weakly if at all by NE. It is selectively inactivated at -40 mV and is selectively blocked by Ni2+, whereas Cd2+ is slightly more potent against the main current. The novel current is associated with a 19 pS channel (0.6 pA at 0 mV). This channel may have been misidentified as the single-channel correlate of the whole-cell N-type Ca2+ current in some previous studies.

Regulation of Shaker K+ channel inactivation gating by the cAMP-dependent protein kinase

In response to depolarization of the membrane potential, Shaker K+ channels undergo a series of voltage-dependent conformational changes, from resting to open conformations followed by a rapid transition into a long-lived closed conformation, the N-type inactivated state. Application of phosphatases to the cytoplasmic side of Shaker channels in excised inside-out patches slows N-type inactivation gating. Subsequent application of the purified catalytic subunit of the cAMP-dependent protein kinase (PKA) and ATP reverses the effect, accelerating N-type inactivation back to its initial rapid rate. Macroscopic and single-channel experiments indicate that N-type inactivation is selectively modulated. There was little or no effect on the voltage dependence and kinetics of activation. Comparison of site-directed mutant channels shows that a C-terminal consensus site for PKA phosphorylation is responsible for the modulation. Since a cell's integrative characteristics can be determined by the rate of inactivation of its voltage-dependent channels, modulation of these rates by phosphorylation is likely to have functional consequences.

Mechanosensitivity of voltage-gated calcium currents in rat anterior pituitary cells

Sensitivity of voltage-activated calcium currents to flow-induced mechanical stress was examined in enriched populations of rat anterior pituitary somatotrophs. Voltage-activated calcium currents were recorded with the whole-cell configuration of the patch-clamp technique. Pituitary cells were exposed to flow (from pipettes) which was produced by a hydrostatic pressure of about 3 cmH2O. In 92% of the cells studied (n = 87 cells) flow reduced the amplitude of both low voltage-activated (LVA) and high voltage-activated (HVA) calcium currents. These effects of flow on calcium currents did not result from changes in either seal resistance or leak conductance of the cell and were dependent on the magnitude of flow. The effect of flow is selective. We found that LVA calcium currents were substantially more sensitive to flow than HVA calcium currents. Under constant flow conditions, LVA calcium currents were reduced by 57.6 +/- 29.6% (S.D.), whereas HVA currents (recorded from the same cells) were reduced by only 17.8 +/- 15.9% (S.D.). The effects of flow on calcium currents were associated with effects on their related calcium tail currents. Slowly deactivating calcium tail currents were reduced by 75.3 +/- 25.6% (S.D.), whereas rapidly deactivating calcium tail currents were reduced by 29.1 +/- 14.4% (S.D.). The effect of flow on calcium currents was not associated with any significant shift in the activation curves of the calcium currents (voltage range -60 to +30 mV), suggesting that the effect of flow is not voltage dependent. The effect of flow is not dependent on activation of calcium currents during the exposure to flow. Calcium currents which were evoked immediately after cessation of the exposure to flow were reduced in amplitude and recovered to control values. Possible mechanisms underlying the flow effect and possible physiological relevance of the effect on pituitary cells are discussed.

Transduction of membrane tension by the ion channel alamethicin

Mechanoelectrical transduction in biological cells is generally attributed to tension-sensitive ion channels, but their mechanisms and physiology remain controversial due to the elusiveness of the channel proteins and potential cytoskeletal interactions. Our discovery of membrane tension sensitivity in ion channels formed by the protein alamethicin reconstituted into pure lipid membranes has demonstrated two simple physical mechanisms of cytoskeleton-independent transduction. Single channel analysis has shown that membrane tension energizes mechanical work for changes of conductance state equal to tension times the associated increase in membrane area. Results show a approximately 40 A2 increase in pore area and transfer of an 80-A2 polypeptide into the membrane. Both mechanisms may be implicated in mechanical signal transduction by cells.

Lipid-glass adhesion in giga-sealed patch-clamped membranes

Adhesion between patch-clamped lipid membranes and glass micropipettes is measured by high contrast video imaging of the mechanical response to the application of suction pressure across the patch. The free patch of membrane reversibly alters both its contact angle and radius of curvature on pressure changes. The assumption that an adhesive force between the membrane and the pipette can sustain normal tension up to a maximum Ta at the edge of the free patch accounts for the observed mechanical responses. When the normal component of the pressure-induced membrane tension exceeds Ta membrane at the contact point between the free patch and the lipid-glass interface is pulled away from the pipette wall, resulting in a decreased radius of curvature for the patch and an increased contact angle. Measurements of the membrane radius of curvature as a function of the suction pressure and pipette radius determine line adhesion tensions Ta which range from 0.5 to 4.0 dyn/cm. Similar behavior of patch-clamped cell membranes implies similar adhesion mechanics.

A cytoskeletal mechanism for Ca2+ channel metabolic dependence and inactivation by intracellular Ca2+

Many different types of voltage-dependent Ca2+ channels inactivate when intracellular ATP declines or intracellular Ca2+ rises. An inside-out, patch-clamp technique was applied to the Ca2+ channels of Lymnaea neurons to determine the mechanism(s) underlying these two phenomena. Although no evidence was found for a phosphorylation mechanism, agents that act on the cytoskeleton were found to alter Ca2+ channel activity. The cytoskeletal disrupters colchicine and cytochalasin B were found to speed Ca2+ channel decline in ATP, whereas the cytoskeletal stabilizers taxol and phalloidin were found to prolong Ca2+ channel activity without ATP. In addition, cytoskeletal stabilizers reduced Ca(2+)-dependent channel inactivation, suggesting that both channel metabolic dependence and Ca(2+)-dependent inactivation result from a cytoskeletal interaction.

Mitochondrial benzodiazepine receptor linked to inner membrane ion channels by nanomolar actions of ligands

The mitochrondrial benzodiazepine receptor (mBzR) binds a subset of benzodiazepines and isoquinoline carboxamides with nanomolar affinity and consists of the voltage-dependent anion channel, the adenine nucleotide translocator, and an 18-kDa protein. The effect of ligands of the mBzR on two inner mitochondrial membrane channel activities was determined with patch-clamp techniques. The relative inhibitory potencies of the drugs resemble their binding affinities for the mBzR. Ro5-4864 and protoporphyrin IX inhibit activity of the multiple conductance channel (MCC) and the mitochondrial centum-picosiemen (mCtS) channel activities at nanomolar concentrations. PK11195 inhibits mCtS activity at similar levels. Higher concentrations of protoporphyrin IX induce MCC but possibly not mCtS activity. Clonazepam, which has low affinity for mBzR, is at least 500 times less potent at both channel activities. Ro15-1788, which also has a low mBzR affinity, inhibits MCC at very high concentrations (16 microM). The findings indicate an association of these two channel activities with the proteins forming the mBzR complex and are consistent with an interaction of inner and outer membrane channels.

Ionic channels in the plasma membrane of Schizosaccharomyces pombe: evidence from patch-clamp measurements

Patch-clamp studies of the yeast Schizosaccharomyces pombe reveal that the plasma membrane contains a voltage-gated channel mildly selective for potassium over sodium, lithium, and chloride. The channel exhibits several conductances with a maximum of 153 pS. The channel gates in the region of physiologically relevant voltages, being closed at hyperpolarizing and open at depolarizing voltages. It is not inhibited by tetraethylammonium, quinine, or quinidine applied from the cytoplasmic side of the membrane; similarly, ATP and stretch have no effect. The frequency of its occurrence in patches implies that about 35 channels of this kind are present in the plasma membrane of a single cell.

A patch-clamp investigation of the Streptococcus faecalis cell membrane

The patch-clamp technique was used to study the membrane of giant protoplasts from the gram-positive bacterium Streptococcus faecalis, demonstrating the presence of ion-conducting pores in the cytoplasmic membrane of procaryotes. The single channel recordings were characterized by a variety of conductances, ranging up to a few nanoSiemens, arising from stretch-activated, voltage-modulated, cooperative channels. Activation by stretch and voltage took place via both a decrease of the mean closed time and an increase of the mean open time of the channels, which are strictly controlled in intact cells, where they might constitute parts of a membrane apparatus or transport system.

Diazoxide-sensitivity of the adenosine 5'-triphosphate-dependent K+ channel in mouse pancreatic beta-cells

1. In mouse pancreatic beta-cells the regulation of the diazoxide-sensitivity of the adenosine 5'-triphosphate-dependent K+ channel (K-ATP-channel) was examined by use of the patch-clamp technique. 2. In intact beta-cells incubated at 37 degrees C in the presence of 3 mM D-glucose, diazoxide did not affect the single channel conductance but stimulated channel-opening activity. Diazoxide produced half-maximal effects at 82 microM and 13 fold activation at maximally effective concentrations (300-400 microM). The response to diazoxide (300 microM) was not completely suppressed by saturating tolbutamide concentrations (1 or 5 mM). 3. Inside-out patch-clamp experiments were carried out using an experimental protocol favouring phosphorylation of membrane proteins. Under these conditions diazoxide was ineffective in the absence of any nucleotides, weakly effective in the presence of MgATP (26 or 87 microM) and strongly effective in the presence of the Mg complexes of adenosine 5'-diphosphate, 2'-deoxyadenosine 5'-diphosphate or guanosine 5'-diphosphate (MgADP, MgdADP or MgGDP). 4. In inside-out patches exposed to nucleotide-free solutions, saturating concentrations of tolbutamide did not cause complete block of K-ATP-channels. When the channels were activated by MgdADP (48 microM), tolbutamide was even less effective. Sensitization of MgdADP-induced channel activation by diazoxide further weakened the effects of tolbutamide. 5. Diazoxide (50 or 300 microM) prevented the complete channel block induced by saturating tolbutamide concentrations in the presence of Mg2+ and ADP (1 mM). 6. In the presence of Mg2", the K-ATP-channel-blocking potency of cytosolic ATP decreased in the order inside-out> outside-out> whole-cell configuration of the patch-clamp technique.7. It is concluded that the K-ATP-channel is controlled via four separate binding sites for inhibitory nucleotides (e.g. free ATP and ADP), stimulatory nucleotides (MgADP, MgdADP, MgGDP), sulphonylureas and diazoxide. Strong inhibition of the channel openings by sulphonylureas results from occupation of both sites for nucleotides. Diazoxide is only effective when the site for stimulatory nucleotides is occupied.

An intracellular medium formulary

Whole-cell patch-clamp recordings allow diffusible intracellular ions and molecules to be replaced by the contents of the recording pipette. In this review, the formulation of intracellular media is considered with a view to improving the stability of recordings and emulating the intracellular environment.

Rapid adaptation of single mechanosensitive channels in Xenopus oocytes

Mechanosensitive (MS) channels are expressed in a wide range of cell types and have been implicated in diverse functions, including osmoregulation and mechanoreception. The majority of previous studies on single MS channels have been carried out on nonsensory cells and have dealt with the steady-state properties of the channel. Here we measure the dynamic or nonstationary properties of the MS channel in Xenopus laevis oocytes. MS channels open transiently in response to a step change in suction applied to the membrane patch. This adaptive behavior occurs because of a reduction in open channel probability rather than a decrease in channel conductance. Double-step suction protocols indicate that adapted MS channels can be reactivated by application of stronger stimulation, consistent with a change in gating sensitivity rather than channel inactivation. Adaptation is highly voltage dependent, being most evident at resting or hyperpolarized potentials and absent at strongly positive potentials. Neither adaptation nor its voltage sensitivity requires the presence of extracellular Ca2+. Adaptation is fragile, dependent on patch history, and can be irreversibly abolished by moderate suction applied to the patch while MS channel activity is retained. Further suction can abolish MS channel activity without compromising the seal. We propose that the selective loss of adaptation and MS channel activity is due to different stages of membrane-cytoskeleton decoupling caused by the mechanical stresses associated with patch clamp recording.

Nuclear ion channels in cardiac myocytes

The paradigm that nucleocytoplasmic transport of ions occurs without a diffusional barrier has been challenged by the recent demonstration with patch-clamp techniques of the existence of ion channels in the nuclear envelope of murine zygotes and hepatocytes. This report demonstrates the existence of nuclear ion channels (NIC) in murine ventricular cardiac myocytes. NIC conductance (gamma), calculated from current histogram peaks, was 106-532 pS at 22-36 degrees C. In nucleus-attached patches, replacement of cytoplasmic K+ with Na+ reduced NIC activity within 30 s, suggesting that intranuclear-delimited mechanisms mediate this phenomenon. In excised, inside-out patches K+ was as permeable as Na+ through NIC. NIC activity was observed in 0-4 mM Mg2+ and/or ATP2-, with or without 0-1 mM Ca2+, indicating a minor direct role of these ions. However, in non-responsive excised inside-out patches, NIC activity appeared when the catalytic subunit of the cAMP-dependent protein kinase was applied to the nucleoplasmic side of the patch, in the presence of Mg2+ and ATP2-, indicating an important role for phosphorylation-dependent process(es) in NIC function--an observation supported by the depressing effects of protein kinase inhibitor on responsive NIC. The concept that nucleopore complexes are solely responsible for nucleocytoplamic transport leads to the speculation that these structures are the physical substrate for NIC.

A 360 degrees single-axis tilt stage for the high-voltage electron microscope

A new type of specimen stage that permits more than 180 degrees of tilting about the axis of a side-entry rod has been developed for a high-voltage electron microscope (HVEM). Roughly cylindrical specimens, with radial dimensions of less than a few micrometers, that can be mounted on the tip of a microneedle or micropipette are applicable. For glass micropipettes, the energy of the 1-MeV beam of the HVEM is sufficient to image specimens through both walls. The stage employs a spindle mechanism that holds these needles or micropipettes coaxial with the tilt axis, allowing the specimen to be rotated without restriction. This arrangement, along with the cylindrical form of the specimen, is an important development for single-axis tomography, because it permits a complete 180 degrees set of projections to be recorded. The angular accuracy of the stage was demonstrated to be within +/- 0.20 degrees, with a cumulative error of less than 1.0 degrees over a 180 degrees span. The new stage was tested using puffball spores mounted on a micropipette. A 180 degrees tilt series was recorded and processed to yield a tomographic three-dimensional reconstruction which was displayed both as a cross-sectional view perpendicular to the tilt axis, and as a shaded surface viewed from different directions. The same computations were repeated using subsets of the tilt series to assess the effect of various amounts of missing information. Visual inspection of a selected cross-section from these reconstructions indicated that limiting the angular range to 160 degrees produced results nearly as good as the full data set. Limiting the range to 140 degrees, however, produced a noticeable geometric distortion, which became increasingly severe with ranges of 120 degrees and 100 degrees.

Gating of maxi K+ channels studied by Ca2+ concentration jumps in excised inside-out multi-channel patches (myocytes from guinea pig urinary bladder)

Currents through maxi K+ channels were recorded in inside-out macro-patches. Using a liquid filament switch (Franke, C., H. Hatt, and J. Dudel. 1987. Neurosci, Lett. 77:199-204) the Ca2+ concentration at the tip of the patch electrode ([Ca2+]i) was changed in less than 1 ms. Elevation of [Ca2+]i from less than 10 nM to 3, 6, 20, 50, 320, or 1,000 microM activated several maxi K+ channels in the patch, whereas return to less than 10 nM deactivated them. The time course of Ca(2+)-dependent activation and deactivation was evaluated from the mean of 10-50 sweeps. The mean currents started a approximately 10-ms delay that was attributed to diffusion of Ca2+ from the tip to the K+ channel protein. The activation and deactivation time courses were fitted with the third power of exponential terms. The rate of activation increased with higher [Ca2+]i and with more positive potentials. The rate of deactivation was independent of preceding [Ca2+]i and was reduced at more positive potentials. The rate of deactivation was measured at five temperatures between 16 and 37 degrees C; fitting the results with the Arrhenius equation yielded an energy barrier of 16 kcal/mol for the Ca2+ dissociation at 0 mV. After 200 ms, the time-dependent processes were in a steady state, i.e., there was no sign of inactivation. In the steady state (200 ms), the dependence of channel openness, N.P(o), on [Ca2+]i yielded a Hill coefficient of approximately 3. The apparent dissociation constant, KD, decreased from 13 microM at -50 mV to 0.5 microM at +70 mV. The dependence of N.P(o) on voltage followed a Boltzmann distribution with a maximal P(o) of 0.8 and a slope factor of approximately 39 mV. The results were summarized by a model describing Ca2+- and voltage-dependent activation and deactivation, as well as steady-state open probability by the binding of Ca2+ to three equal and independent sites within the electrical field of the membrane at an electrical distance of 0.31 from the cytoplasmic side.

Light-activated ion channels in solitary photoreceptors of the scallop Pecten irradians

Retinas from the scallop Pecten irradians were enzymatically dispersed, yielding a large number of isolated photoreceptors suitable for tight-seal recording. Whole-cell voltage clamp measurements demonstrated that the phototransducing machinery remained intact: quantum bumps could be elicited by dim illumination, while brighter flashes produced larger, smooth photocurrents. Single-channel currents specifically activated by light were recorded in cell-attached patches, and were almost exclusively confined to the rhabdomeric region. Their density is sufficiently high to account for the macroscopic photoresponse. Channel activation is graded with stimulus intensity in a range comparable to that of the whole-cell response, and can be recorded with illumination sufficiently dim to evoke only quantum bumps. Light-dependent channel openings are very brief, on average 1 ms or less at 20-22 degrees C, apparently not because of blockage by extracellular divalent cations. The mean open time does not change substantially with stimulus intensity. In particular, since dwell times are in the millisecond range even with the dimmest lights, the channel closing rate does not appear to be the rate-limiting step for the decay kinetics of discrete waves. The latency of the first opening after light onset is inversely related to light intensity, and the envelope of channel activity resembles the time course of the whole-cell photocurrent. Unitary currents are inward at resting potential, and have a reversal voltage similar to that of the macroscopic light response. Voltage modulates the activity of light-sensitive channels by increasing the opening rate and also by lengthening the mean open times as the patch is depolarized. The unitary conductance of the predominant class of events is approximately 48 pS, but at least one additional category of smaller-amplitude openings was observed. The relative incidence of large and small events does not appear to be related in a simple way to the state of adaptation of the cell.

Single-channel dose-response studies in single, cell-attached patches

A method for carrying out dose-response studies of ion channel currents in cell-attached patches has been devised. Patch pipettes are filled at the tip with a solution containing one concentration of ligand and then backfilled with another. The concentration of ligand at the membrane is described as a function of time by the equation for diffusion in a cone, allowing response vs. time data to be transformed into a dose-response curve. For Xenopus myocyte cholinergic receptors, examples of the use of this method are given for several concentration-dependent reactions including blockade by the local anesthetic QX-222, activation by acetylcholine, and modulation of current amplitude by sodium ions. Several methods of analyzing the nonstationary channel kinetics are presented, including a pseudo-stationary approach that uses interval likelihood maximization.