Multiple neuropeptides exert a direct effect on the same isolated single smooth muscle cell

Using total fluorescence increase (signal mass) to determine the Ca2+ current underlying localized Ca2+ events

The feasibility of determining localized Ca(2+) influx using only wide-field fluorescence images was explored by imaging (using fluo-3) single channel Ca(2+) fluorescence transients (SCCaFTs), due to Ca(2+) entry through single openings of Ca(2+)-permeable ion channels, while recording unitary channel currents. Since the image obtained with wide-field optics is an integration of both in-focus and out-of-focus light, the total fluorescence increase (DeltaF(total) or "signal mass") associated with a SCCaFT can be measured directly from the image by adding together the fluorescence increase due to Ca(2+) influx in all of the pixels. The assumptions necessary for obtaining the signal mass from confocal linescan images are not required. Two- and three-dimensional imaging was used to show that DeltaF(total) is essentially independent of the position of the channel with respect to the focal plane of the microscope. The relationship between Ca(2+) influx and DeltaF(total) was obtained using SCCaFTs from plasma membrane caffeine-activated cation channels when Ca(2+) was the only charge carrier of the inward current. This relationship was found to be linear, with the value of the slope (or converting factor) affected by the particular imaging system set-up, the experimental conditions, and the properties of the fluorescent indicator, including its binding capacity with respect to other cellular buffers. The converting factor was used to estimate the Ca(2+) current passing through caffeine-activated channels in near physiological saline and to estimate the endogenous buffer binding capacity. In addition, it allowed a more accurate estimate of the Ca(2+) current underlying Ca(2+) sparks resulting from Ca(2+) release from intracellular stores via ryanodine receptors in the same preparation.

Modulation of BK(Ca) channel activity by fatty acids: structural requirements and mechanism of action

To determine the mechanism of fatty acid modulation of rabbit pulmonary artery large-conductance Ca2+ -activated K+ (BK(Ca)) channel activity, we studied effects of fatty acids and other lipids on channel activity in excised patches with patch-clamp techniques. The structural features of the fatty acid required to increase BK(Ca) channel activity (or average number of open channels, NP(o)) were identified to be the negatively charged head group and a sufficiently long (C > 8) carbon chain. Positively charged lipids like sphingosine, which have a sufficiently long alkyl chain (C >or= 8), produced a decrease in NP(o). Neutral and short-chain lipids did not alter NP(o). Screening of membrane surface charge with high-ionic-strength bathing solutions (330 mM K+ or 130 mM K+, 300 mM Na+) did not alter the modulation of the BK(Ca) channel NP(o) by fatty acids and other charged lipids, indicating that channel modulation is unlikely to be due to an alteration of the membrane electric field or the attraction of local counterions to the channel. Fatty acids and other negatively charged lipids were able to modulate BK(Ca) channel activity in bathing solutions containing 0 mM Ca2+, 20 mM EGTA, suggesting that calcium is not required for this modulation. Together, these results indicate that modulation of BK(Ca) channels by fatty acids and other charged lipids most likely occurs by their direct interaction with the channel protein itself or with some other channel-associated component.

Visualization of Ca2+ entry through single stretch-activated cation channels

Stretch-activated channels (SACs) have been found in smooth muscle and are thought to be involved in myogenic responses. Although SACs have been shown to be Ca(2+) permeable when Ca(2+) is the only charge carrier, it has not been clearly demonstrated that significant Ca(2+) passes through SACs in physiological solutions. By imaging at high temporal and spatial resolution the single-channel Ca(2+) fluorescence transient (SCCaFT) arising from Ca(2+) entry through a single SAC opening, we provide direct evidence that significant Ca(2+) can indeed pass through SACs and increase the local [Ca(2+)]. Results were obtained under conditions where the only source of Ca(2+) was the physiological salt solution in the patch pipette containing 2 mM Ca(2+). Single smooth muscle cells were loaded with fluo-3 acetoxymethyl ester, and the fluorescence was recorded by using a wide-field digital imaging microscope while SAC currents were simultaneously recorded from cell-attached patches. Fluorescence increases at the cell-attached patch were clearly visualized before the simultaneous global Ca(2+) increase that occurred because of Ca(2+) influx through voltage-gated Ca(2+) channels when the membrane was depolarized by inward SAC current. From measurements of total fluorescence ("signal mass") we determined that about 18% of the SAC current is carried by Ca(2+) at membrane potentials more negative than the resting level. This would translate into at least a 0.35-pA unitary Ca(2+) current at the resting potential. Such Ca(2+) currents passing through SACs are sufficient to activate large-conductance Ca(2+)-activated K(+) channels and, as shown previously, to trigger Ca(2+) release from intracellular stores.

Coupling of a P2Z-like purinoceptor to a fatty acid-activated K(+) channel in toad gastric smooth muscle cells

1. Extracellular application of ATP generates two whole-cell currents in toad gastric smooth muscle cells: an immediate inward non-selective cation current (due to the activation of a P2X or P2Z-like receptor) and a slowly developing outward K(+) current. The inward non-selective cation current depends on the continuous presence of ATP while the outward K(+) current can last for minutes after ATP application ceases. 2. In cell-attached patches, application of ATP to the extra-patch membrane can activate K(+) channels in the patch indicating that a diffusible cellular messenger may be involved. The characteristics of these K(+) channels are similar to those of a previously described fatty acid-activated K(+) channel that is also a stretch-activated channel. 3. This whole-cell K(+) current can be induced by ATP in the absence of extracellular Ca(2+) (with EGTA present to chelate trace amounts). However, the current generated in the presence of extracellular Ca(2+) is considerably larger. 4. The pharmacological profiles for the activation of the non-selective cation current and the K(+) current are similar, suggesting that the same P2Z-like receptor could be mediating both responses. This type of plasma membrane receptor/channel-channel coupling by a process that does not appear to involve Ca(2+) flow through the receptor/channel or a subsequent membrane potential change may be representative of a new class of signalling mechanisms.

Multiple pathways responsible for the stretch-induced increase in Ca2+ concentration in toad stomach smooth muscle cells

1. A digital imaging microscope with fura-2 as the Ca2+ indicator was used to determine the sources for the rise in intracellular calcium concentration ([Ca2+]i) that occurs when the membrane in a cell-attached patch is stretched. Unitary ionic currents from stretch-activated channels and [Ca2+]i images were recorded simultaneously. 2. When suction was applied to the patch pipette to stretch a patch of membrane, Ca2+-permeable cation channels (stretch-activated channels) opened and a global increase in [Ca2+]i occurred, as well as a greater focal increase in the vicinity of the patch pipette. The global changes in [Ca2+]i occurred only when stretch-activated currents were sufficient to cause membrane depolarization, as indicated by the reduction in amplitude of the unitary currents. 3. When Ca2+ was present only in the pipette solution, just the focal change in [Ca2+]i was obtained. This focal change was not seen when the contribution from Ca2+ stores was eliminated using caffeine and ryanodine. 4. These results suggest that the opening of stretch-activated channels allows ions, including Ca2+, to enter the cell. The entry of positive charge triggers the influx of Ca2+ into the cell by causing membrane depolarization, which presumably activates voltage-gated Ca2+ channels. The entry of Ca2+ through stretch-activated channels is also amplified by Ca2+ release from internal stores. This amplification appears to be greater than that obtained by activation of whole-cell Ca2+ currents. These multiple pathways whereby membrane stretch causes a rise in [Ca2+]i may play a role in stretch-induced contraction, which is a characteristic of many smooth muscle tissues.

Imaging Ca(2+) entering the cytoplasm through a single opening of a plasma membrane cation channel

Discrete localized fluorescence transients due to openings of a single plasma membrane Ca(2+) permeable cation channel were recorded using wide-field digital imaging microscopy with fluo-3 as the Ca(2+) indicator. These transients were obtained while simultaneously recording the unitary channel currents using the whole-cell current-recording configuration of the patch-clamp technique. This cation channel in smooth muscle cells is opened by caffeine (Guerrero, A., F.S. Fay, and J.J. Singer. 1994. J. Gen. Physiol. 104:375-394). The localized fluorescence transients appeared to occur at random locations on the cell membrane, with the duration of the rising phase matching the duration of the channel opening. Moreover, these transients were only observed in the presence of sufficient extracellular Ca(2+), suggesting that they are due to Ca(2+) influx from the bathing solution. The fluorescence transient is characterized by an initial fast rising phase when the channel opens, followed by a slower rising phase during prolonged openings. When the channel closes there is an immediate fast falling phase followed by a slower falling phase. Computer simulations of the underlying events were used to interpret the time course of the transients. The rapid phases are mainly due to the establishment or removal of Ca(2+) and Ca(2+)-bound fluo-3 gradients near the channel when the channel opens or closes, while the slow phases are due to the diffusion of Ca(2+) and Ca(2+)-bound fluo-3 into the cytoplasm. Transients due to short channel openings have a "Ca(2+) spark-like" appearance, suggesting that the rising and early falling components of sparks (due to openings of ryanodine receptors) reflect the fast phases of the fluorescence change. The results presented here suggest methods to determine the relationship between the fluorescence transient and the underlying Ca(2+) current, to study intracellular localized Ca(2+) handling as might occur from single Ca(2+) channel openings, and to localize Ca(2+) permeable ion channels on the plasma membrane.

An ATP-gated cation channel with some P2Z-like characteristics in gastric smooth muscle cells of toad

1. Whole-cell and single-channel currents elicited by extracellular ATP were studied in freshly dissociated smooth muscle cells from the stomach of the toad Bufo marinus using standard patch clamp and microfluorimetric techniques. 2. This ATP-gated cation channel shares a number of pharmacological and functional properties with native rat myometrium receptors, certain native P2Z purinoceptors and the recently cloned P2X7 purinoceptor. But, unlike the last two, the ATP-gated channel does not mediate the formation of large non-specific pores. Thus, it may represent a novel member of the P2X or P2Z class. 3. Extracellular application of ATP (> or = 150 microM) elicited an inward whole-cell current at negative holding potentials that was inwardly rectifying and showed no sign of desensitization. Na+, Cs+ and, to a lesser degree, the organic cation choline served as charge carriers, but Cl- did not. Ratiometric fura-2 measurements indicated that the current is carried in part by Ca2+. The EC50 for ATP was 700 microM in solutions with a low divalent cation concentration. 4. ATP (> or = 100 microM) at the extracellular surface of cell-attached or excised patches elicited inwardly rectifying single-channel currents with a 22 pS conductance. Cl- did not serve as a charge carrier but both Na+ and Cs+ did, as did choline to a lesser extent. The mean open time of the channel was quite long, with a range in hundreds of milliseconds at a holding potential of -70 mV. 5. Mg2+ and Ca2+ decreased the magnitude of the ATP-induced whole-cell currents. Mg2+ decreased both the amplitude and the activity of ATP-activated single-channel currents. 6. ADP, UTP, P1, P5-di-adenosine pentaphosphate (AP5A), adenosine and alpha, beta-methylene ATP (alpha, beta-Me-ATP) did not induce significant whole-cell current. ATP-gamma-S and 2-methylthio ATP (2-Me-S-ATP) were significantly less effective than ATP in inducing whole-cell currents, whereas benzoylbenzoyl ATP (BzATP) was more effective. BzATP, alpha, beta-Me-ATP, ATP-gamma-S and 2-Me-S-ATP induced single-channel currents, but a higher concentration of alpha, beta-Me-ATP was required. 7. BzATP did not induce the formation of large non-specific pores, as assayed using mag-fura-2 as a high molecular mass probe.

Bombesin-mediated calcium fluxes in myenteric plexus neurons

Dual excitation microfluorimetry (Fura-2) was used to measure changes in intracellular calcium ([Ca2+]i) in individual cultured guinea pig myenteric neurons. Bombesin (5-500 nM) induced concentration-dependent increases in [Ca2+]i responses, with a maximal effect at 500 nM (56% of neurons responding, mean peak Ca2+ response 244 +/- 25 nM vs. basal 65 +/- 7 nM). Removal of Ca2+ from the median did not affect the initial [Ca2+]i peak but eliminated the subsequent plateau phase. The [Ca2+]i responses to bombesin was abolished by preincubation with thapsigargin (1 microM), a Ca(2+)-ATPase inhibitor (91 +/- 7% inhibition). [Ca2+]i responses to bombesin were inhibited by U73122 (1 microM), an inhibitor of phospholipase C (84 +/- 6% inhibition).

A simple technique for on-line measurement of contractions of single smooth muscle fibers under current or voltage clamp

This paper describes a simple technique for routine on-line measurement of length and unloaded, isotonic contractions of single smooth muscle fibers during electrophysiological experiments. The fiber is held by the recording electrode itself, stretched straight in a fast-flowing stream of solution. The video image of the fiber is measured on-line by a simple computer program. Unlike other optical methods of tracking fiber length, the technique does not require a rigid one-dimensional contraction of the fiber. The technique is reliable and easy to use, and readily compatible with current clamp, voltage clamp, and rapid reversible application of neurotransmitters and drugs.

Structural requirements for charged lipid molecules to directly increase or suppress K+ channel activity in smooth muscle cells. Effects of fatty acids, lysophosphatidate, acyl coenzyme A and sphingosine

We determined the structural features necessary for fatty acids to exert their action on K+ channels of gastric smooth muscle cells. Examination of the effects of a variety of synthetic and naturally occurring lipid compounds on K+ channel activity in cell-attached and excised membrane patches revealed that negatively charged analogs of medium to long chain fatty acids (but not short chain analogs) as well as certain other negatively charged lipids activate the channels. In contrast, positively charged, medium to long chain analogs suppress activity, and neutral analogs are without effect. The key requirements for effective compounds seem to be a sufficiently hydrophobic domain and the presence of a charged group. Furthermore, those negatively charged compounds unable to "flip" across the bilayer are effective only when applied at the cytosolic surface of the membrane, suggesting that the site of fatty acid action is also located there. Finally, because some of the effective compounds, for example, the fatty acids themselves, lysophosphatidate, acyl Coenzyme A, and sphingosine, are naturally occurring substances and can be liberated by agonist-activated or metabolic enzymes, they may act as second messengers targeting ion channels.

Aluminofluoride activates hyperpolarization- and stretch-activated cationic channels in single smooth muscle cells

Aluminofluoride (AF) has a variety of biological actions such as activation of GTP binding proteins and inhibition of phosphatases. In the present study, the effects of AF on hyper-polarization- and stretch-activated cationic channels (HA-SACs) were investigated in isolated gastric smooth muscle cells from the toad, Bufo marinus, using the patch-clamp technique. In cell-attached patches extracellular application of AF (20 mM KF plus 20 microM AlCl3) reversibly increased HA-SAC activity without changing its voltage sensitivity. The single channel current amplitude of HA-SACs was not affected during this procedure. The mechanism of AF-induced activation of HA-SACs remains unclear. However, this activation may play a role in contraction of smooth muscle induced by AF.

Stretch-inactivated cationic channels in single smooth muscle cells

Stretch-inactivated channels (SICs) were identified in single smooth muscle cells freshly dissociated from the stomach of the toad, Bufo marinus. In both cell-attached and excised inside-out patches, negative pressure applied to the extracellular surface of the membrane patch suppressed the activity of SICs. These channels were permeable to cations and were not significantly permeable to Cl-. The current-voltage relationship showed outward rectification in cell-attached patches with high NaCl in the pipette solution (2 mM MgCl2), and the slope conductance at negative potentials was approximately 8 pS under these conditions. When divalent cations were eliminated from the pipette solution, the slope conductance at negative potentials increased to approximately 30 pS. No significant voltage dependence of SIC gating could be observed between -100 mV and 60 mV.

Cholinergic activation of a non-selective cation current in canine gastric smooth muscle is associated with contraction

1. The effects of acetylcholine on membrane electrical properties of single smooth muscle cells dissociated from the circular layer of the canine gastric corpus were investigated using the nystatin perforated patch technique. Cells retained their ability to contract during recording, making it possible to correlate changes in membrane potential and membrane currents with contractions. 2. Acetylcholine caused depolarization from -59 +/- 8 mV to -18 +/- 7 mV (means +/- S.D., n = 12) with no generation of action potentials. The depolarization was associated with a membrane conductance increase, consistent with acetylcholine activating an inward current. In addition, acetylcholine caused contraction of cells to 58% of initial length. Both depolarization and contraction were reversible and were antagonized by atropine. 3. Under voltage clamp, acetylcholine activated inward current associated with increased current noise. The current-voltage relationship of the acetylcholine-induced current was studied at steady-state voltages and with voltage ramp commands. The inward current was largest between -40 and -20 mV and reversed direction to outward close to 0 mV (reversal potential, Erev = +3 +/- 9 mV). Reduction of external Na+ concentration to 21 mM shifted Erev to -42 +/- 5 mV, as predicted for a non-selective cation current. The conductance activated by acetylcholine (gACh) increased sigmoidally with depolarization, with about 2.5 nS activated at 0 mV. 4. Cells consistently contracted upon stimulation with acetylcholine, even when studied under voltage clamp at potentials as negative as -100 mV. This was consistent with muscarinic receptor activation causing release of Ca2+ from internal stores. When cells were bathed in Ca(2+)-free solutions, the first application of acetylcholine elicited normal inward current and contraction. Thereafter, both inward current and contractions were greatly diminished or absent, suggesting that the stores of Ca2+ had been depleted. 5. Caffeine caused reversible contraction and activation of inward current similar to that elicited by acetylcholine. 6. It is concluded that muscarinic stimulation of canine gastric smooth muscle cells involves activation of a non-selective cation conductance and is consistently accompanied by contraction. The release of Ca2+ from internal stores may be a common trigger for both events.

Both membrane stretch and fatty acids directly activate large conductance Ca(2+)-activated K+ channels in vascular smooth muscle cells

Large conductance Ca(2+)-activated K+ channels in rabbit pulmonary artery smooth muscle cells are activated by membrane stretch and by arachidonic acid and other fatty acids. Activation by stretch appears to occur by a direct effect of stretch on the channel itself or a closely associated component. In excised inside-out patches stretch activation was seen under conditions which precluded possible mechanisms involving cytosolic factors, release of Ca2+ from intracellular stores, or stretch induced transmembrane flux of Ca2+ or other ions potentially capable of activating the channel. Fatty acids also directly activate this channel. Like stretch activation, fatty acid activation occurs in excised inside-out patches in the absence of cytosolic constituents. Moreover, the channel is activated by fatty acids which, unlike arachidonic acid, are not substrates for the cyclo-oxygenase or lypoxygenase pathways, indicating that oxygenated metabolites do not mediate the response. Thus, four distinct types of stimuli (cytosolic Ca2+, membrane potential, membrane stretch, and fatty acids) can directly affect the activity of this channel.

Multiple types of Ca2+ channels in visceral smooth muscle cells

Single-channel currents were recorded from two classes of Ca2+ channels in visceral smooth muscle cells isolated from the stomach of the toad, Bufo marinus: a class of small-conductance channels (approximately 11 pS) and a class of large-conductance channels (approximately 26 pS). Small-conductance channels were present in a majority of patches and gave rise to a slowly inactivating current (t1/2 approximately 250 ms at 0 mV). Openings of large-conductance channels could be unequivocally resolved only in the presence of the dihydropyridine Ca2+ agonist Bay K 8644. Two subtypes of the large-conductance channels were found--those with a very slow rate of decay (greater than 500 ms) and those with a faster one (less than 100 ms). Large-conductance channels resemble L-type Ca2+ channels of other preparations. Small-conductance channels do not fit unambiguously into the other existing categories (i.e., N or T). Correspondence between single-channel and macroscopic Ca2+ currents is discussed.

Hyperpolarization-activated cationic channels in smooth muscle cells are stretch sensitive

The properties of hyperpolarization-activated channels were studied in single smooth muscle cells from the stomach of the toad, Bufo marinus, using the patch-clamp technique. In cell-attached patches, inward channel currents were activated by hyperpolarizing pulses from a holding potential of -20 mV to potentials more negative than -60 mV. The activity of the channels increased and their latency of activation decreased as the hyperpolarization was increased. The slope conductance of the channels with standard high sodium concentration pipette solution was 64.2 +/- 9.1 pS (SD, n = 17). Stretching the patch, by suction applied to the back of the patch pipette, also increased the activity and shortened the latency of activation. We designate these channels as HA-SACs (hyperpolarization- and stretch-activated channels). HA-SACs were observed in 83% (175/210) of the patches studied. HA-SAC currents were carried by sodium and potassium ions, but their amplitude was increased by replacing extracellular sodium with potassium. Extracellular magnesium and calcium ions significantly reduced the single-channel conductance of HA-SACs. These permeation characteristics and the single-channel conductance of HA-SACs were indistinguishable from those of stretch-activated channels (SACs) previously described in these cells. The following observations are consistent with HA-SACs being a subset of SACs. First, SACs were at times found in cell-attached patches which lacked HA-SACs. Second, the number of channels in a cell-attached patch simultaneously activated by stretch (usually 5-10 and often more) exceeded by far the number simultaneously activated by hyperpolarization (usually one or two).(ABSTRACT TRUNCATED AT 250 WORDS)

Dual regulation of M current in gastric smooth muscle cells: beta-adrenergic-muscarinic antagonism

The effects of the beta-adrenergic agent isoproterenol on membrane currents were studied in freshly dissociated gastric smooth muscle cells of Bufo marinus. Voltage-clamp experiments were carried out with patch pipettes in the tight-seal, whole-cell recording mode or with conventional microelectrodes. Isoproterenol induced a current identified as M current by the following criteria: the induced current is outward and carried by K+ ions, is suppressed by muscarine or acetylcholine, remains steadily activated, turns off with hyperpolarization, and exhibits slow relaxations in response to voltage jumps. In contrast to endogenous M current, isoproterenol-induced M current usually exhibited slower relaxations on hyperpolarizing voltage commands and displayed a steady-state conductance/voltage relationship that was shifted in the negative direction along the voltage axis. M current was also induced by either forskolin or phosphodiesterase-resistant cAMP analogs. In all cases, muscarinic agonists suppressed the M current, apparently by acting at a locus downstream from regulation of cAMP levels by adenylate cyclase and phosphodiesterase. beta-Adrenergic agents may act to increase the number of M channels available to be opened and also modify their kinetics.

Expression of functional neurotransmitter receptors in an uninnervated tissue: avian amnion

The smooth muscle of the avian amnion is unusual because it is normally never innervated. However, as assessed by contractile response, this tissue expressed at least 11 different types of receptor for neurotransmitter substances including acetylcholine, norepinephrine, histamine, 5-hydroxytryptamine, vasoactive intestinal peptide, urotensin II, neurotensin, and somatostatin-28. Three neurotransmitters, histamine, 5-hydroxytryptamine, and norepinephrine, each acted via 2 separate and antagonistic types of receptors. The amnion also responded to prostaglandin E2. On the other hand, the tissue did not respond to substance P or bradykinin, 2 peptides that are known to affect smooth muscle contractility in a variety of other systems. Studies with organ-cultured amnion demonstrated that the smooth muscle can be cultured early in development and will differentiate in vitro. Some, but not all, of the amniotic responses developed in a defined medium. The results indicate that this novel smooth muscle preparation will be useful for identifying epigenetic factors that control the expression of functional receptors.

Substance P, like acetylcholine, augments one type of Ca2+ current in isolated smooth muscle cells

Electrophysiological recordings from freshly-dissociated smooth muscle cells from toad stomach revealed that substance P enhances one of two types of Ca2+ currents. That is, substance P enhances the slowly inactivating, high-threshold current but not the fast inactivating, low-threshold current. Acetylcholine has the same effect, but the acetylcholine action is blocked by atropine whereas the substance P action is not, indicating that the two agents act at different receptor sites. Thus, substance P, like acetylcholine, has a dual excitatory action on the smooth muscle cells employed in these studies, enhancing a specific type of Ca2+ current, as demonstrated here, and suppressing a voltage-sensitive K+ conductance, as previously described [Sims, S.M., Walsh, J.V., Jr. & Singer, J.J. (1986) Am. J. Physiol. 251, C580-C587].

Stretch-activated ion channels in smooth muscle: a mechanism for the initiation of stretch-induced contraction

As in many smooth muscle tissue preparations, single smooth muscle cells freshly dissociated from the stomach of the toad Bufo marinus contract when stretched. Stretch-activated channels have been identified in these cells using patch-clamp techniques. In both cell-attached and excised inside-out patches, the probability of the channel being open (Po) increases when the membrane is stretched by applying negative pressure to the extracellular surface through the patch pipette. The increase in Po is mainly due to a decrease in closed time durations, but an increase in open time duration is also seen. The open-channel current-voltage relationship shows inward rectification and is not appreciably altered when K+ is substituted for Na+ as the charge-carrying cation in Ca2+-free (2 mM EGTA) pipette solutions bathing the extracellular surface of the patch. The inclusion of physiological concentrations of Ca2+ (1.8 mM) in pipette solutions (containing high concentrations of Na+ and low K+) significantly decreases the slope conductance as well as the unitary amplitude. The channel also conducts Ca2+, since inward currents were observed using pipette solutions in which Ca2+ ions were the only inorganic cations. When simulating normal physiological conditions, we find that substantial ionic current is conducted into the cell when the channel is open. These characteristics coupled with the high density of the stretch-activated channels point to a key role for them in the initiation of stretch-induced contraction.

Antagonistic adrenergic-muscarinic regulation of M current in smooth muscle cells

The beta-adrenergic agonist isoproterenol and analogs of adenosine 3',5'-monophosphate (cAMP) induced a potassium current, M current, in freshly dissociated gastric smooth muscle cells. Muscarinic agonists suppress this current, apparently by acting at a locus downstream from regulation of cAMP levels by adenylate cyclase and phosphodiesterase. Thus, M current can be induced by an agent and regulated in antagonistic fashion by beta-adrenergic and muscarinic systems.

Acetylcholine increases voltage-activated Ca2+ current in freshly dissociated smooth muscle cells

The regulation of voltage-activated Ca2+ current by acetylcholine was studied in single freshly dissociated smooth muscle cells from the stomach of the toad Bufo marinus by using the tight-seal whole-cell recording technique. Ca2+ currents were elicited by positive-going command pulses from a holding level near -80 mV in the presence of internal Cs+ to block outward K+ currents. Ca2+ current was greatest in magnitude at command potentials near 10 mV. At such command potentials, acetylcholine increased the magnitude of the inward current and slowed its decay. The effects of acetylcholine were seen in the absence of external Na+ or with low Cl- (aspartate replacement) in the bathing solution and could be mimicked by muscarine. The peak of the current-voltage relationship for the Ca2+ current was not discernibly shifted along the voltage axis by acetylcholine. These results demonstrate that activation of muscarinic receptors not only suppresses a K+ current (M-current), as we have previously demonstrated [Sims, S. M., Singer, J. J. & Walsh, J. V., Jr. (1985) J. Physiol. (London) 367, 503-529], but also increases the magnitude and slows the decay of Ca2+ current.

Characterization of calcium-activated potassium channels in single smooth muscle cells using the patch-clamp technique

Single-channel currents were recorded with the patch-clamp technique from freshly dissociated vertebrate smooth muscle cells from the stomach of Bufo marinus. Of the variety of channels observed, one displayed a large linear conductance of 250 pS (in symmetric 130 mM KCl) which in excised patches was shown to be highly K+ selective. The probability of the channel being open (Po) increased when [Ca2+]i was elevated and/or when the membrane potential was made more positive. Thus, the features of this channel resemble the large-conductance Ca2+-activated K+ channel found in a wide variety of cell types. The voltage sensitivity of the channel was studied in detail. For patches containing a single large-conductance channel a plot of Po versus membrane potential followed the Boltzmann relationship. Increasing [Ca2+]i shifted this plot to the left along the voltage axis to more negative potentials. Both the mean closed time and mean open time varied with potential as a single exponential with almost all of the voltage sensitivity of Po residing in the mean closed time. These results were verified with a series of experiments carried out at low Po (less than 0.1) in patches containing multiple (N) large-conductance channels. Here the ln (NPo) was a linear function of potential with an inverse slope of 9 mV. Almost all of the potential sensitivity lay in the mean closed time the natural log of which was also a linear function of potential with an inverse slope 11 mV in magnitude. The characteristics of this channel as well as the appearance of several of them in almost every patch suggest that they underlie the large peak outward macroscopic current found with whole-cell voltage-clamp studies.