Potassium Currents in Freshly Dissociated Uterine Myocytes from Nonpregnant and Late-Pregnant Rats

S.Y. Wang, M. Yoshino, J.L. Sui, M. Wakui, P.N. Kao, and C.Y. Kaodagger

From the Department of Pharmacology, State University of New York Health Science Center, Brooklyn, New York 11203

    ABSTRACT
Top
Abstract
Introduction
Methods
Results
Discussion
References

In freshly dissociated uterine myocytes, the outward current is carried by K+ through channels highly selective for K+. Typically, nonpregnant myocytes have rather noisy K+ currents; half of them also have a fast-inactivating transient outward current (ITO). In contrast, the current records are not noisy in late pregnant myocytes, and ITO densities are low. The whole-cell IK of nonpregnant myocytes respond strongly to changes in [Ca2+]o or changes in [Ca2+]i caused by photolysis of caged Ca2+ compounds, nitr 5 or DM-nitrophene, but that of late-pregnant myocytes respond weakly or not at all. The Ca2+ insensitivity of the latter is present before any exposure to dissociating enzymes. By holding at -80, -40, or 0 mV and digital subtractions, the whole-cell IK of each type of myocyte can be separated into one noninactivating and two inactivating components with half-inactivation at approximately -61 and -22 mV. The noninactivating components, which consist mainly of iberiotoxin-susceptible large-conductance Ca2+-activated K+ currents, are half-activated at 39 mV in nonpregnant myocytes, but at 63 mV in late-pregnant myocytes. In detached membrane patches from the latter, identified 139 pS, Ca2+-sensitive K+ channels also have a half-open probability at 68 mV, and are less sensitive to Ca2+ than similar channels in taenia coli myocytes. Ca2+-activated K+ currents, susceptible to tetraethylammonium, charybdotoxin, and iberiotoxin contribute 30-35% of the total IK in nonpregnant myocytes, but <20% in late-pregnant myocytes. Dendrotoxin-susceptible, small-conductance delayed rectifier currents are not seen in nonpregnant myocytes, but contribute ~20% of total IK in late-pregnant myocytes. Thus, in late-pregnancy, myometrial excitability is increased by changes in K+ currents that include a suppression of the ITO, a redistribution of IK expression from large-conductance Ca2+-activated channels to smaller-conductance delayed rectifier channels, a lowered Ca2+ sensitivity, and a positive shift of the activation of some large-conductance Ca2+-activated channels.

Key words: smooth muscle cellsuterine myocytesK+ channelspregnancyovarian hormones
    INTRODUCTION
Top
Abstract
Introduction
Methods
Results
Discussion
References

Under influences of ovarian hormones and during pregnancy, ionic currents of uterine myocytes undergo some profound changes, such as the emergence of a high-affinity tetrodotoxin-sensitive Na+ current, and its increasing density relative to a coexisting Ca2+ current as pregnancy progresses to term (Yoshino et al., 1997). Another striking change occurs in the outward current where a noisy Ca2+-sensitive K+ current, prominent in nonpregnant and early-pregnant myocytes, is largely replaced by a smooth Ca2+-insensitive current in late-pregnant myocytes (Kao et al., 1989; Wang et al., 1996). Such a transformation could be due to changes in the properties of some K+ channels, to changes in the relative roles of different types of K+ channels, or combinations of these possibilities.

Multiple types of K+ currents have been known for some time (see Hille, 1992), and more than a score of different K+ channels have been identified by recombinant DNA methods (Chandy and Gutman, 1995; Jan and Jan, 1997). A chief aim of this work is to determine the contributions of different K+ channels to the total outward current of uterine myocytes at different stages of pregnancy in the rat. To this end, we separated the whole-cell K+ currents of nonpregnant and late-pregnant myocytes into components containing fewer overlapping currents, and studied their kinetic and steady state gating properties, responsiveness to intra- and extracellular Ca2+, and susceptibility to selective blocking agents. We also examined single-channel properties of the large-conductance Ca2+-activated K+ channel and related them to whole-cell K+ currents. We find that during pregnancy the expression of the outward current shifts from these channels to other types of K+ channel, and that the shift together with other changes in K+ currents can increase myometrial excitability. Preliminary accounts of some of this work have been presented (Suput et al., 1989; Kao et al., 1989; Yoshino et al., 1989, 1997; Wang et al., 1996).

    METHODS
Top
Abstract
Introduction
Methods
Results
Discussion
References

Multicellular Preparations

Myometrial strips were taken from pregnant rats of known gestation. Small strands of the longitudinal myometrium were studied in a double sucrose-gap chamber, where the region ("node") under current or voltage clamp averaged 65 µm, with total capacitance of ~100 pF (Kao and McCullough, 1975). The nodes, formed by interfaces of flowing sucrose and Krebs solution, are now known to contain ~1,000 myocytes (Yoshino et al., 1997). Aside from being dissected free from the uterus and subjected to two cuffs of high-resistance isotonic sucrose solution, these strands were not exposed to any enzymes or mechanical disruptions, nor were their cell interior exposed to any artificial Ca2+ buffers.

Dissociated Myocytes and Single-Channels Studies

Myocytes were obtained from nonpregnant (estrus phase) and late-pregnant (17-21 d) rat uteri (see details in Yoshino et al., 1997). The main differences for the present study lie in the use of some agents and solutions for specific projects to sort out different types of K+ channels. They are 4-aminopyridine (Hach Chemical Co., Ames, IA), charybdotoxin (Calbiochem Corp., San Diego, CA), iberiotoxin (Peptides International, Louisville, KY), dendrotoxin (Calbiochem Corp.), apamin (ICN Biochemicals Inc., Costa Mesa, CA), mast-cell degranulating peptide (Peninsula Laboratory, Belmont, CA), nitr-5 and DM-nitrophene (Calbiochem Corp.).

In experiments to identify charge carriers of the outward current, the bath solution contained (mM): 140 KCl, 0.6 EGTA, and 0.01 CaCl2, pH 7.3, with a maximum free [Ca2+] of 7 nM. To test the role of Cl- in the outward current, the 140 mM KCl was replaced with 100 mM K2SO4, the two being equiosmolar as determined by osmometry.

Photolysis of Caged Ca2+ Compounds

These experiments aimed at increasing intracellular Ca2+ ([Ca2+]i) directly to see how the outward current might be affected. An inverted microscope with an epifluorescence attachment was used (Diaphot; Nikon Inc., Melville, NY). The photolabile caged Ca2+ compound, nitr 5 (Gurney et al., 1987), was introduced into the cell by diffusion from the pipette, which contained 2 mM nitr 5, 1 mM Ca2+, and 140 mM K+. Filtered light of 330-380 nm was focused onto the myocyte through a 40 × "Fluor" objective (Nikon Inc.) that had a numerical aperture of 0.85 and transmittance to 340 nm. Exposure was controlled by a shutter (Vincent Associates, Rochester, NY). The photoenergy was insufficient to produce "flash" photolysis, and exposures lasted 100-800 ms. Such long exposures did not interfere with our interest in steady state effects. DM-nitrophene, another caged Ca2+ compound (Kaplan, 1990) was used in a generally similar way.

The concentration of Ca2+ attained on photolysis of nitr 5-Ca was estimated under simulated conditions. Ca2+-selective microelectrodes were made by introducing a neutral Ca2+-selective ion exchange resin (ETH 1001; World Precision Instruments, New Haven, CT; Amman, 1986) into the first 200 µm of previously silanized microelectrodes with tip openings of 1-1.5 µm. In standard solutions of pCa 7 to 3, the response of the microelectrodes was linear from pCa 6.5 to 3, with a slope of 29 mV/pCa U. Between pCa 7 and 6.5, the slope was 20 mV. To estimate the [Ca2+] released by photolysis, a Ca2+ microelectrode and a reference electrode were placed in a 10-µl droplet of the pipette solution within the microscope field. The droplet was exposed to UV light for 10-800 ms. The response of the microelectrode stabilized within 26 to 40 s. The basal [Ca2+] before UV exposure was 0.4- 0.47 µM (six trials; see also Gurney et al., 1987). Upon irradiation, the increment of [Ca2+] was 0 µM for 10 ms, 1.8 µM for 100 ms, 8.2 µM for 400 ms, 14.6 µM for 800 ms, and 44 µM on continuous exposure. The true [Ca2+]i attained must be less because of the presence of additional Ca2+-buffering system in the cell.

Single-Channel Studies

Detached inside-out patches were used because [Ca2+]i could be confidently controlled and readily altered. Openings identified as K+ channels were surveyed, and large-conductance Ca2+-activated K+ channels were selected for study. The methods used were similar to those described for other smooth myocytes (taenia coli, Hu et al. 1989a,b; Fan et al., 1993; ureter, Sui and Kao, 1997). Separated or overlapped openings of different amplitudes were considered as different channels rather than subconductance levels of the same channel, because the larger (assumed full) and smaller (assumed sublevels) openings were random and unrelated. Overlapped openings of the same amplitude were assumed to be of the same channel type. In each condition, 1,000-10,000 channel events were collected. The records were examined for the highest overlap level in the more active recordings taken at highly positive voltages (80 mV), and in high [Ca2+] (pCa 6). Relative activities of different types of channels were determined by analyzing all channel openings during a recording period in 0.1 pA bins every 150-200 µs. The number of channels in a patch was derived from the highest overlapped opening level; and the averaged single channel activities were calculated for all channels. The average open-probability (Po) for patches with multiple channels of the same amplitude was estimated when the number of channels in the patch could be reasonably determined. When the number of channels was uncertain, the open-probability was shown as nPo.

In RESULTS, averaged values are given as means ± SEM. Significance of differences were evaluated by Student's t test in either the paired or unpaired form, as appropriate.

    RESULTS
Top
Abstract
Introduction
Methods
Results
Discussion
References

charge carrier of the outward current

In the myometrium, at the usual resting potential of approximately -50 mV, ECl is approximately -20 mV (Kao and Siegman, 1963); in principle, Cl- influx during depolarization could contribute to the whole-cell outward current (Parkington and Coleman, 1990). The charge carrier is identified as follows: when uterine myocytes were immersed in 140 mM KCl or 100 mM K2SO4 (pCa = 8.13), the resting potential was close to 0. When they were held to -80 mV, and then depolarized, the steady state current (at 0.5 s) was inward at negative voltages and outward at positive voltages. This phenomenon was confirmed in nine myocytes, regardless of whether Cl- or SO42- was the anion. The 0-mV reversal potential observed under asymmetric chloride concentrations indicates that potassium is the dominant charge carrier.

whole-cell k+ currents of uterine myocytes and their responses to ca2+

The outward currents of freshly dissociated nonpregnant and late pregnant uterine myocytes are quite different with regard to time dependence, relative amplitudes, inherent noise, and calcium dependence. To delineate separate potassium channel contributions, it is necessary first to differentiate the general properties of the outward current in the nonpregnant and late-pregnant myocytes.

Nonpregnant Myocytes

In nonpregnant myocytes (Fig. 1, A-C), the outward currents first appeared at approximately -30 mV. At ~0 mV, they began to exhibit frequent large fluctuations (noisy) and distinct outward rectification. When elicited from a holding potential (HP)1 of -80 mV, about half of the myocytes had an initial surge that peaked at 3.8 ± 0.5 ms (10 myocytes), and then fell in another few milliseconds to merge into a current that rose and declined more slowly (Fig. 1 A). The initial surge is due to a transient outward current (ITO). In the other half of nonpregnant myocytes, no ITO was present and the current rose gradually to reach a maximum at 24.8 ± 2.6 ms (10 myocytes). In both types of myocytes, the outward current decayed appreciably. In myocytes with an ITO, the current was ~50% of the maximum by 235 ms (see current-voltage relations in Fig. 1 C) and ~20% by 1.1 s (not shown). In myocytes without an ITO, the current was ~80% by 235 ms and ~50% by 1.1 s (data not shown). In either case, the noisiness and the extensive decay distinguish the outward current of the nonpregnant myocyte from that of the late-pregnant myocyte.


View larger version (30K):
[in this window]
[in a new window]
 
Fig. 1.   Outward currents of typical nonpregnant and late-pregnant rat uterine myocytes. Currents at HP -80 and -50 mV are shown at same scales for comparison (depolarized for 258 ms in 10-mV increments to +70 mV). Symbols above top current traces indicate where current was measured for i-V curves. (A-C) Nonpregnant myocytes, 16.8 pF. Current has frequent and large fluctuations (noisy). (A) HP -80 mV. ITO is clearly visible, peaking at ~3.5 ms, declining rapidly to a more gradual current that reached maximum at 33 ms. From this maximum, decay is faster than in late-pregnant myocytes (D). Also note greater outward rectification. (B) Same myocyte, HP -50 mV. ITO is now absent (see inactivation relation in Fig. 6 A). Maximum current is 41% of that at HP -80 mV. Current noise remains about the same; decay is less. (C) i-V relations. Note the differences between maximum current and end-of-pulse current, indicating degree of decay; also obvious outward rectification. (D-F) Myocyte from 19-d pregnant uterus; cell capacitance 108 pF. (D) HP -80 mV. Currents develop gradually, reaching a maximum at ~35 ms. Currents are generally smooth, with little noise fluctuations. They are also well-sustained over several hundred milliseconds. More decay is evident over several seconds. First current appeared at approximately -40 mV. Some outward rectification is evident to 0 mV; thereafter, rectification is slight. In traces from -20 to 20 mV, a small early distortion may be the transient outward current. (E) Same myocyte at HP -40 mV. Total current is now 17% that at HP -80 mV. No decay is evident. (F) i-V relations of currents at maximum and at end. Note that outward rectification is very slight, as is decay.


View larger version (31K):
[in this window]
[in a new window]
 
Fig. 6.   Steady state activation and inactivation properties of component currents of nonpregnant and late-pregnant uterine myocytes. (A) Properties of ITO in nonpregnant myocytes. For V-h relation (left curve and ordinate ; data from six myocytes shown as means ± SEM, if scatter is larger than symbol), two-pulse protocol similar to those for Fig. 5 was used. Solid curve is Boltzmann distribution function with half inactivation at -76.5 mV and a slope of 6.9 mV. At -50 mV, the relative current is 0.01; at -40 mV, 0.001. For V-g relation (right curve and ordinate ; eight myocytes), relative conductance as a function of maximum conductance was obtained for each myocyte as the asymptotic value at 120 mV. Half activation is at +5 mV with a slope factor of 24.3 mV. (B-D) Properties of component currents. See test for paradigm of extracting C1, C2, and C3 currents. In these panels, data from nonpregnant myocytes are represented by hollow symbols and their Boltzmann distribution by solid lines. Data from late-pregnant myocytes are represented by filled symbols, and their Boltzmann distribution functions by broken lines. In B and C, V-h relations are rescaled from Fig. 5. (B) Properties of C1 currents. For nonpregnant myocytes (data from seven myocytes which had no ITO), half activation is at 7.2 mV with a slope factor of 24.6 mV. For late-pregnant myocytes (data from 22 myocytes), half activation is at 7.7 mV with a slope factor of 23.7 mV. "Window current" is present in both types of myocytes. (C) Properties of C2 currents. For nonpregnant state (seven myocytes), half activation is at 3.9 mV with a slope factor of 17.7 mV. For late-pregnant state (11 myocytes), half activation is at 4.2 mV with a slope of 22.1 mV. Window currents are larger than those in C1 currents. (D) Properties of C3 currents that do not inactivate. For nonpregnant state (seven myocytes), half activation is at 39.1 mV, slope 17.7 mV. For late-pregnant state (12 myocytes), half activation is at 63.4 mV, slope 16.7 mV. Half-activation voltages are significantly different (see text for details).


View larger version (19K):
[in this window]
[in a new window]
 
Fig. 5.   Voltage-steady state inactivation relation of outward current in nonpregnant and late-pregnant myocytes. Two-step protocol, holding potential -80 mV, conditioning step 10 s duration, test step 180 ms. Current of test step in presence and absence of the conditioning step is plotted on ordinate as relative current. Conditioning voltage on abscissa. Symbols are data (means ± SEM). (A) Nonpregnant myocytes. Data from eight myocytes (9.2, 18, 9.2, 11, 15.4, 25, 13.6, and 16.4 pF). The complex relation requires three components for fitting. C1, comprising 59% of total K+ current, is half inactivated at -59.5 mV, with a slope factor of 13.4 mV. C2, comprising 30%, is half inactivated at -22.9 mV with a slope of 4.1 mV. C3, comprising 11%, does not inactivate. (B) Late-pregnant myocytes. Data from seven myocytes; three from 17-d pregnant uteri (89, 58, and 82.4 pF); two from 18-d pregnant uteri (80 and 96 pF), and two from 19-d pregnant uteri (93 and 180.4 pF). The complex relation also requires three components: C1, comprising 67% of total IK, is half inactivated at -62.7 mV, with a slope factor of 6.3 mV; C2, comprising 23%, is half inactivated at -21.2 mV, with a slope factor of 5.7 mV; and C3, comprising 10%, does not inactivate. Although the half-inactivation voltages and slope factors are similar to those of nonpregnant myocytes, C1 has enlarged at the expense of C2.

When elicited from -50 mV, ITO was absent (Fig. 1 B). The slower current was about half that at HP -80 mV. This current declined to ~90% by 235 ms (Fig. 1 C), and to ~75% by 1.1 s. The lesser decay resembled that of the late-pregnant myocyte, but the noisiness remained.

Fig. 2, A and B, shows the typical responses of nonpregnant myocytes to a rise in [Ca2+]o. At HP -80 mV, when all types of K+ channels were expressed, raising [Ca2+]o to 30 mM had little effect on the average current (see small difference current in Fig. 2 A, A3). At HP -50 mV, at which ITO was absent, raising [Ca2+]o markedly increased the total IK (Fig. 2 B, B1). The initial surge peaked at 2.8 ms and had all the kinetic features of the ITO (Fig. 2 B, B2). At +70 mV, the ITO was 3.7× larger, and the steady state IK (at 245 ms) was 1.9× larger than the isochronal currents in 1 mM Ca2+ (Fig. 2 B, B3). Similar changes were seen in five other nonpregnant myocytes.


View larger version (34K):
[in this window]
[in a new window]
 
Fig. 2.   Effects of [Ca2+]o on outward currents of nonpregnant and late-pregnant rat uterine myocytes. (A and B) Nonpregnant rat in estrus; cell capacitance 5.0 pF. (A) Holding potential -80 mV, depolarized for 245 ms in 10-mV increments to 70 mV. (A1) In 1 mM Ca2+. Note presence of a ITO. (A2) In 30 mM Ca2+. Little effect, possibly because all currents are fully expressed. (A3) Difference between currents in 30 and 1 mM Ca2+ verify the general lack of effects of increasing [Ca2+]o. (B) HP -50 mV; same voltage protocol. (B1) In 1 mM Ca2+, ITO is inactivated; current rises gradually and is maintained for 245 ms with little decay. (B2) 30 mM Ca2+. Marked increase in outward current, mostly in ITO, but also some in steady state current, as is evident in difference current (B3). (C and D) Late-pregnant myocytes; from 17-d pregnant uterus (C), cell capacitance 106 pF; from 18-d pregnant uterus (D), cell capacitance 102 pF. Cells were held at -60 mV, and depolarized by 150-ms steps in 10-mV increments to 40 mV. (C1-3) Effects of lowering [Ca2+]o from 3 to 0 mM. (C1) In 3 mM Ca2+, inward ICa was present and IK was well maintained. (C2) In 0 mM Ca2+, ICa disappeared but IK is essentially unchanged. (C3) Difference current between C2 and C1. Note that difference current represents the inward ICa, with little difference in IK. (D1-3) Effects of raising [Ca2+]o from 3 to 30 mM. Conventions similar to those in C1-3. (D1) In 3 mM Ca2+, ICa and IK serve as bases for comparison. (D2) In 30 mM Ca2+, ICa increased appreciably, but IK remained essentially unchanged. (D3) Difference current shows changes in ICa, but little change in IK.

Late-Pregnant Myocytes

In late-pregnant myocytes (Fig. 1, D-F), the outward current first appeared at approximately -30 mV. Up to -10 mV, some outward rectification was evident, but, more positive than -10 mV, rectification was slight. The currents at all voltages have few fluctuations (smooth). Typically, they rose gradually to reach a maximum at 32.5 ± 2.1 ms (31 myocytes). Although an early rapid phase was apparent at small depolarizations from HP -80 mV (Fig. 1 D), no ITO similar to those in nonpregnant myocytes were seen in any late-pregnant myocyte. For ~300 ms, the currents were well sustained (at ~90% by 235 ms; Fig. 1 F), but at >1-2 s, some decline occurred (at ~60% by 2.1 s, not shown). From HP -50 mV, the current was smaller than that from HP -80 mV, and showed similar little decay, remaining at ~90% at 235 ms, and ~80% at 2.1 s.

Fig. 2, C and D, show the typical responses of changing [Ca2+]o on the IK of two late-pregnant myocytes. Although reducing [Ca2+]o to 0 mM (Fig. 2 C), or raising it to 30 mM (Fig. 2 D) led to a disappearance or an increase of the inward ICa, respectively, IK remained virtually unchanged (see also difference currents in Fig. 2, C, C3, and D, D3). A similar stability of IK in different [Ca2+]o was observed in 11 other late-pregnant myocytes. In five of these, ICa had first been blocked with Co2+ (5 mM), and the stability of IK was the same as those in myocytes with ICa.

Ca2+-insensitive IK as an Intrinsic Property of Late-Pregnant Uterine Myocytes

To exclude a possible artifactual nature of the unexpected Ca2+-insensitive IK of late-pregnant myocytes, we turned to evidence gathered on small multicellular preparations in which the myocytes were neither exposed to proteolytic enzymes nor their interior to EGTA. Fig. 3 shows that, in a double sucrose-gap method, such preparations produced action potentials under current-clamp conditions and ionic currents under voltage-clamp conditions. In these preparations, effects of procedures on IK can be gauged by comparing the current at 500 ms, when the inward current had inactivated. Mn2+ (5 mM), which blocked the inward Ca2+ current, had no effect on the IK (Fig. 3 A). A similar outcome was observed with Co2+ (3 mM; not shown). Conversely, when [Ca2+]o was raised, the inward current increased, but the steady state outward current was not appreciably different (Fig. 3 B). These results show that Ca2+-insensitive IK is present before cell dissociation, and represents an intrinsic physiological property of late-pregnant myocytes.


View larger version (14K):
[in this window]
[in a new window]
 
Fig. 3.   Responses of small multicellular preparations of late-pregnant myometrium to conditions that affect inward ICa. Double sucrose-gap method. (A) Effects of Mn2+ (5 mM). Preparation from 19-d pregnant uterus. Total "nodal" capacitance, 0.1 µF. (A1) Action potential elicited by constant current step. (A2) Action potential after 5 min of superfusion with Krebs solution containing Mn2+, showing blockade. (A3-6) Superimposed composite currents under voltage-clamp conditions. Numbers at left margin of each trace represent command voltage step. Traces marked 1 are from control conditions, traces marked 2 are from after treatment with Mn2+. Note that whereas Mn2+ effectively blocked inward ICa, it produced no detectable changes in steady state IK. (B) Effects of increasing [Ca2+]o from 1.9 to 8 mM. Preparation from 20-d pregnant uterus. Total nodal capacitance, 0.07 µF. (B1) Action potential elicited by constant current in 1.9 mM Ca2+. (B2) Action potential in 8 mM Ca2+ shows a faster rate of rise and a higher amplitude, consistent with increased ICa. (B3-6) Superimposed composite currents under voltage-clamp conditions. Traces marked 1 are from 1.9 mM Ca2+, traces marked 2 are from 8 mM Ca2+. Because of limitations of method, effects of procedures on IK can only be examined at steady state (500 ms) when inward current has inactivated. Note that, whereas increased [Ca2+]o increased ICa and increased overlap artifact in the early part of the outward current, it did not produce significant changes of steady state IK. The constancy of IK in these preparations, which were not treated with enzymes and their myocyte interior was not exposed to EGTA, is consistent with similar observations made on dissociated myocytes.

Effects of Photolysis-Released Ca2+i on IK of Different Types of Myocytes

To avoid altering surface negative charges that can occur when manipulating [Ca2+]o, the effects of [Ca2+]i on IK can be tested by use of caged calcium compounds, nitr 5, and DM-nitrophene.

Nitr 5-Ca complex was diffused from the pipette solution into myocytes to which it imparted a brownish fluorescence. Unirradiated, nitr 5 had no effect on the depolarization-induced IK, which was identical in density and kinetics to that in myocytes without nitr 5. In other control myocytes, irradiation, in the absence of nitr 5, produced no effect on the depolarization- induced IK. The effects of irradiating cells containing nitr 5-Ca complex were tested on 15 nonpregnant and 36 late-pregnant uterine myocytes, and 29 guinea pig taenia coli myocytes (for comparative control). Fig. 4 shows the responses in the different types of cells.


View larger version (21K):
[in this window]
[in a new window]
 
Fig. 4.   Effects of photolysis-induced increase of [Ca2+]i on nonpregnant, late-pregnant uterine myocytes and on taenia coli myocyte. Caged nitr 5-Ca complex was introduced intracellularly by diffusion from pipette (see text for details). In each panel, five consecutive traces, recurring at 3-s intervals, are shown. Traces marked C represent three superimposed traces of depolarization-induced whole-cell IK in cells that have been loaded with nitr 5-Ca complex, but not irradiated. Traces marked F represent the fourth trace, during which myocyte was exposed to 360 nm light at time indicated by bar beneath traces. Traces marked F+1 represent the fifth trace in series. (A and B) Nonpregnant myocytes, 10.6 and 8.4 pF, respectively. In A, average IK showed an increase upon irradiation. The increase in this cell is unusually large. Other changes also evident include more prominent current noise, downward shift of baseline, indicating holding current became more inward, and larger tail current. In B, increase in current noise is especially evident. (C-E) Late-pregnant myocytes; from 18-d pregnant uterus, 78 (C) and 60 (D) pF, and 19-d pregnant uterus, 120 pF (E). These examples show representative responses in late-pregnant myocytes. (C) Typical of 44% of test samples (36 myocytes), this cell showed no response. (D) In this myocyte, in addition to an increase in average IK, there was an inward shift of holding current, an increase in tail current, and an increase of current noise. (E) In this myocyte, response consisted of an increase in average IK and in current noise. 56% of all samples responded as in D and E. (F) Response of a representative taenia coli myocyte, which is known to have abundant maxi-K channels. Large increase in average IK and increase in current noise occurred in 97% of 29 cells tested.

All 15 nonpregnant myocytes loaded with the nitr 5- Ca complex responded to irradiation with an increase in the IK (Fig. 4, A and B), which averaged 4.8 ± 1.5-fold over the control (nonirradiated) IK. The current noise was larger (Fig. 4 B), the holding current became slightly inward, and the tail current was bigger (Fig. 4 A). All these changes are consistent with an activation of a large-conductance K+ channel.

In late-pregnant myocytes, the responses were varied. 16 myocytes (44%) showed no response (Fig. 4 C) and 20 myocytes (56%) showed an IK increased by 2.0 ± 0.3-fold (Fig. 4, D and E). In all responding myocytes, the current noise increased, but an inward holding current was seen in only 13 myocytes (Fig. 4 D). Pooling the responding and nonresponding myocytes, the average irradiation-induced increase in IK was 1.5 ± 0.2-fold over the control current. Thus, Ca2+-activated K+ channels, while present in late-pregnant myocytes, are expressed at a lower level.

By contrast, in guinea pig taenia coli myocytes in which whole-cell IK is mostly due to large-conductance Ca2+-activated K+ channels (Yamamoto et al., 1989; Hu et al., 1989; Fan et al., 1993), 28 myocytes (97%) responded to irradiation with a 5.3 ± 0.9-fold increase in IK (Fig. 4 F). To address possible species differences, in three myocytes from the analogous rat cecum, irradiation increased the average IK by 21.9 ± 3.3-fold above the control level.

DM-nitrophene (Kaplan, 1990) was tested on 24 late-pregnant myocytes. The qualitative changes observed with DM-nitrophene were similar in every respect to those seen using nitr 5-Ca: the irradiation-induced increases in [Ca2+]i always caused much smaller increases in IK in late-pregnant uterine myocytes than in taenia coli myocytes.

paradigm for analyzing whole-cell iK of uterine myocytes

From the evidence presented above, the whole-cell IK of nonpregnant and late-pregnant uterine myocytes are complex and substantially different from each other. In the following, we will attempt to sort and apportion the components of IK in each type of myocyte.

Basis of Paradigm: Steady State Availability of K+ Currents

Fig. 5 shows the voltage-steady state inactivation (V-h) relation of the outward current, obtained on eight nonpregnant and seven late-pregnant myocytes. Each myocyte was held at -80 mV, first subjected to a 10-s conditioning voltage step, and then to a 180-ms test step of up to +70 mV to elicit outward currents. The data are complex, and can only be fitted by assuming the presence of three populations of currents with distinct Boltzmann distribution functions. Two of the components inactivate at depolarized potentials, whereas a third does not. For nonpregnant myocytes (Fig. 5 A), the inactivating components represent 59 (C1) and 30% (C2) of the total current, with half-inactivating voltages at -59.5 and -22.9 mV, respectively. The noninactivating component (C3) represents 11% of the current. For late-pregnant myocytes (Fig. 5 B), the inactivating components are 67% for C1 and 23% for C2, with half-inactivation voltages, respectively, at -62.7 and -21.2 mV. The noninactivating component (C3) represents 10% of the total. Thus, in pregnancy, the C1 component enlarged at the expense of the C2 component.

These results suggest that a paradigm using holding potentials, -80, -40 (or -50), and 0 mV, can sort the whole-cell IK into smaller components. Holding at 0 mV gives the noninactivating component (C3). Holding at -40 mV gives the C2 and C3 components, whereas the difference between these currents yields the C2 component. Holding at -80 mV gives the total IK, and the difference between currents from HP -80 and -40 mV yields the C1 component. Thus, currents in the C3 component are excluded from the C2 component, as are currents in the C2 and C3 components from the C1 component. A residue of C1 currents remains in the combined C2, C3 components, but its relative size can be estimated from the V-h curves.

This paradigm can be assessed by evaluating the average current densities (Table I) observed on a larger sample of myocytes used in other experiments. From a group of nonpregnant myocytes, separate from those used in the V-h study, the total current density at HP -80 mV was 41.4 pA/pF (Table I). On the basis of the V-h relation (Fig. 5 A), this total might be apportioned as: C1, 24.4 pA/pF (59%); C2, 12.4 pA/pF (30%), and C3, 4.6 pA/pF (11%). Outward currents elicited from HP -40 mV contain components C2 and C3, which are the same as above, and a residue of C1, which is 10.7% (Fig. 5 A) or 4.4 pA/pF. So, the deduced total current for HP -40 mV is 21.4 pA/pF, which can be compared with the observed value of 21.6 pA/pF (Table I).

                              
View this table:
[in this window]
[in a new window]
 

Table I
Some Properties of IK of Uterine Myocytes

For late-pregnant myocytes, the total outward current elicited from HP -80 mV was 40.1 pA/pF (Table I), which can be apportioned as: C1, 26.9 pA/pF (67%); C2, 9.2 pA/pF (23%), and C3, 4 pA/pF (10%). At HP -50 mV, the C2 and C3 components are the same as above, and the residual C1 (8.3%; Fig. 5 B) is 3.3 pA/pF. Therefore, the total deduced current for HP -50 mV is 16.5 pA/pF, which is close to the observed current of 17.1 pA/pF (Table I).

The paradigm was further tested by gauging the sizes of the various components on six late-pregnant myocytes. Each of these cells was held successively at -80, -40, and 0 mV, and IK at +70 mV and 200 ms were compared. The fractional sizes were: C1, 0.67 ± 0.07 (six myocytes); C2, 0.23 ± 0.04; and C3, 0.09 ± 0.03, comparable with those derived from the V-h relations (Fig. 5 B).

Such close agreements support a general usefulness of the paradigm. Although each component still contains multiple currents, there are fewer and some overlap can be estimated. For clarity of later presentation, we will refer to the various components by their pregnancy status and designation as used in Fig. 5. Thus, ILP1 refers to the C1 component of late-pregnant myocytes, and INP2 refers to the C2 component of nonpregnant myocytes, etc. When two components are not separated, they are designated as the sum of the two, ILP2,3, etc.

components of the whole-cell k+ psi theta rho rho epsilon nu tau

Because the components contain fewer overlapping currents than the whole-cell IK, detailed scrutiny of their kinetic and steady state activation and inactivation properties (see Fig. 6), their Ca2+ sensitivity (see Fig. 7), and their susceptibility to blocking agents (see Figs. 8-12) may lead to a better understanding of the differences between nonpregnant and late-pregnant uterine myocytes.


View larger version (31K):
[in this window]
[in a new window]
 
Fig. 7.   Effects of [Ca2+]o on activation of component currents of whole-cell IK in nonpregnant and late-pregnant uterine myocytes. Symbols represent means ± SEM of five nonpregnant (A and B) and nine late-pregnant myocytes (C and D). Solid lines represent Boltzmann distributions. In nonpregnant but not late-pregnant myocytes, 30 mM Ca2+ caused a positive shift of V-g relation.


View larger version (20K):
[in this window]
[in a new window]
 
Fig. 8.   Effects of tetraethylammonium chloride on component currents of IK of late-pregnant uterine myocytes. (A-C) TEA, 0.5 mM. (D) TEA, 2 mM. In A and B, traces of residual current in TEA (ITEA, light traces) are overlaid on traces of current before TEA (Icontrol, heavy traces) at same voltages. For clarity, only selected traces are shown. (A) Myocyte from 20-d pregnant uterus, 191 pF. Traces shown are ILP1's, which are difference currents between those obtained at HP -90 and -40 mV. (B) Traces shown are ILP2,3, obtained directly by recording at HP -40 mV. TEA reduction of average current is associated with marked reduction of peak-to-peak current fluctuations. The y-axis labels (0, 30, and 60 mV) identify Icontrol current records of ILP2,3(heavy traces), and 0.5 mM TEA causes reductions in the current at each voltage step (light traces, below). At faster time scales (not shown), TEA does not affect activation kinetics (for 60-mV step, tau control = 13 ms, tau TEA = 15 ms). (C) Difference currents, Icontrol - ITEA at all voltage steps for myocytes in A, representing currents blocked by TEA (5.7 pA/pF at 60 mV), which does not decay over 2.1 s. Calibrations are the same as in A. (D) TEA, 2 mM. Myocyte from 17-d pregnant uterus; 126.6 pF. Traces are difference currents, Icontrol - ITEA, at all voltages. Although it caused a greater block (12.6 pA/pF at 60 mV, 2.1 s) than other higher concentrations, their effects involve also some decaying component, making them less useful for differentiating channel types.


View larger version (30K):
[in this window]
[in a new window]
 
Fig. 9.   Effects of charybdotoxin (100 nM) on IK of uterine myocytes. Conventions are similar to those in Fig. 8, except that A and E represent directly recorded total currents; IChTX (light traces) overlaid on Icontrol (heavy traces). (C, D, G, and H) are different currents, or currents blocked by ChTX. (A-D) Nonpregnant myocyte. 18.4 pF. ChTX reduced peak-to-peak current fluctuations. In A, ITO is distinct in traces of -10, 10, and 30 mV in Icontrol, and is blocked by ChTX. In B, at HP -50 mV, only INP2,3 is elicited. Effects of ChTX are rather small, and are not manifested until more positive than 50 mV. (C) Difference currents, Icontrol - IChTX at HP -80 mV. For clarity, only two traces at fast time scale are shown. Note the particularly prominent block on the ITO, manifested here as an initial surge, peaking at 3 ms. The subsequent current seen in the 70-mV trace is clearly of a different and noisy type. In the full trace (not shown), the blocked current shows no decay. (D) Difference currents, Icontrol - IChTX at HP -50 mV confirm that ChTX had no effect until beyond 50 mV. (E-H) Myocyte from 20-d pregnant uterus; 117.6 pF. At HP -80 (E) and -50 (F) mV, IChTX for the -10-mV trace is superimposed on Icontrol. (G) Difference currents, Icontrol - IChTX for HP -80 mV, on a fast time scale. The blocked currents show an initial hump, contrast with the blocked ITO in C, followed by another sustained current. (H) Difference currents, Icontrol - IChTX at HP -50 mV.


View larger version (32K):
[in this window]
[in a new window]
 
Fig. 10.   Effects of iberiotoxin (1 nM) on IK of uterine myocytes. Selected traces for clarity. IIbTX traces are lighter and overlaid on Icontrol traces from the same voltages. (A-D) Nonpregnant myocyte with ITO; 18 pF. (A) HP -80 mV, showing total IK. (B) HP -40 mV, showing INP2,3 for same voltage steps as in A. (C) Difference currents, Icontrol - IIbTX at HP -80 mV, (C1) at a fast time scale to show that initial part of the blocked current coincided with ITO. (D) Difference currents at HP -40 mV. (E-G) Nonpregnant myocyte without ITO; 18 pF. (E) HP -80 mV. (F) HP -40 mV. Traces are of same voltages as in E. (G) HP 0 mV, showing INP3. IbTX reduces peak-to-peak fluctuations and average currents, most notably in INP3, but also evident in directly recorded currents (A, B, E, and F), and as difference currents (C and D). Other features of note: (a) IbTX effect is not evident until V > 20 mV (A and E), probably because susceptible current is not activated; (b) IbTX blocks a part of the ITO at all voltages (A and C1), but the blocked current is different from that blocked by ChTX (Fig. 9), suggesting that ITO is not a homogenous current; (c) unlike most maxi-K currents shown, some IbTX-susceptible currents show an appreciable rate of decay (C2). (H-K) Late-pregnant myocytes. (H) Myocyte from an 18-d pregnant uterus, 105.4 pF. HP -90 mV. This myocyte has very little IbTX-susceptible currents, as can also be seen in difference currents in J. (I) Myocyte from 18-d pregnant uterus, 137 pF. Main responses are similar to those described for nonpregnant myocyte. Difference currents are shown in K.


View larger version (27K):
[in this window]
[in a new window]
 
Fig. 11.   Effects of 4-aminopyridine on IK of uterine myocytes. Selected traces for clarity. I4-AP (light traces) overlaid on Icontrol of same voltage steps. (A-D) Nonpregnant myocyte with ITO, 15.6 pF. 4-AP, 5 mM. While 4-AP markedly reduced total IK (A) and INP2,3 (B), it did not block the ITO (A), as also shown in difference currents in C. It also did not reduce current fluctuations in direct recording (B), or in difference currents (D). These effects are consistent with 4-AP actions on Kv channels. (E-G) Myocyte from 18-d pregnant uterus. 162 pF. 4-AP, 1 mM. (E) HP -90 mV, showing total IK. Note that current at 2.1 s (end of step) is slightly more depressed by 4-AP than current at 35 ms (maximum), a feature also seen in dose-response relations in H. (F    and G) HP -40 mV, showing ILP2,3. Noisy current is obvious at +60 mV, but 4-AP has no effect on peak-to-peak fluctuations. Slowing of the rate of activation by 4-AP is already evident, but more so at a faster time scale in G. At 60 mV, tau control = 36 ms, tau 4-AP = 64 ms. This effect on kinetics could cause the wrong conclusion that 4-AP is selective for some transient current. Comparing E and F, and also A and B, it is clear that main effects of 4-AP are exerted on the C1 components (ILP1 and INP1). (H) Dose-response relation of 4-AP on currents at 35 ms (Imax; hollow symbols) and at 2.1 s (filled symbols). Hill plot, abscissa, log concentration; ordinate, (1 - P)/P where P is I4-AP/Icont. ED50 is at 1 - P/P = 1. IK at 2.1 s is almost three times more susceptible than Imax.


View larger version (32K):
[in this window]
[in a new window]
 
Fig. 12.   Effects of dendrotoxin (200 nM) on IK of uterine myocytes. In all panels, IDTX (light trace) is overlaid on Icontrol. For clarity, only selected traces are shown. (A and B) Nonpregnant myocyte, 19.2 pF. (A) HP -80 mV, eliciting total IK. (B) HP -40 mV, eliciting INP2,3. DTX has no effect on this myocyte. (C and D) Myocyte from 19-d pregnant uterus, 93.2 pF. (C) HP -80 mV. Total IK is reduced slightly by DTX (IDTX/Icont = 0.96 at maximum current and 0.97 at end). (D) HP -40 mV. DTX effect on ILP2,3 is appreciable (IDTX/Icont = 0.54 at maximum and at end). Note that in DTX, current fluctuations are unchanged. Effects are consistent with DTX blocking a delayed rectifier current (see text for details).

Component Currents of Nonpregnant Myocytes

Transient outward current. ITO was isolated as the difference current between currents elicited from holding potentials -80 and -50 mV. In 11 of 21 nonpregnant myocytes examined, a distinct ITO was seen. In late-pregnant myocytes, a small transient surge was sometimes seen at small depolarizations, but positive to -10 mV, no current of similarly fast kinetics was ever prominent. Therefore, ITO is discussed here as a K+ current exclusively of nonpregnant myocytes.

ITO activated with an exponential time course; the time-constant (tau ) was slightly voltage dependent, averaging 3 ms at -10 mV and 1.5 ms at +60 and +70 mV. However, the variations were large, possibly because of variations in the ambient temperature during the experiment (see Conner and Stevens, 1971). ITO inactivated with a tau  of 3 ms that was not voltage dependent.

The voltage-conductance (V-g) relations of ITO followed Boltzmann distribution closely, with half-activation at 5 mV and a slope of 24.3 mV (Fig. 6 A). The maximum conductance was 664 ± 106 µs/cm2 (nine myocytes). The voltage-inactivation relation obtained in a two-step command protocol showed half-inactivation at -76.5 mV, with a slope of 6.9 mV (Fig. 6 A). By -40 mV, only 0.1% of ITO was available.

Other K+ currents. The other K+ currents of nonpregnant myocytes are analyzed by using myocytes that had no ITO. The development and decay of INP1 (difference current between those from HP -80 and -40 mV) and INP2 (difference current between HP -40 and 0 mV) were exponential. The activation was voltage dependent, and tau  for INP1 (10 ± 2 ms at +20 mV, 6 ± 1 ms at +70 mV; 11 myocytes) was faster than tau for INP2 (19 ± 3 ms at +20 mV, 9 ± 2 ms at +70 mV; 4 myocytes). The activation of INP3 (HP 0 mV) was instantaneous. The inactivation of INP1 was voltage independent, with an average tau  of 110 ms. INP2 and INP3 did not decay over 1.2 s.

In Fig. 6, the steady state activation and inactivation properties of INP1 (Fig. 6 B), INP2 (Fig. 6 C), and INP3 (Fig. 6 D) are shown in hollow symbols, and their Boltzmann distributions in full lines. Half-activation voltages and the associated slopes are given in Table I, as are the maximum conductances. The V-h relations in Fig. 6, B and C, were rescaled from Fig. 5 A, and the half-inactivation voltages and associated slopes are given in Table I. In both cases, there was an overlap with the activation curves, encompassing 12% of the maximum at -40 mV for INP1, and 30% of the maximum at -20 mV for INP2.

When [Ca2+]o was increased from 1 to 30 mM, the activation curves of both INP1 and INP2,3 shifted to the positive, with the V0.5, act moving 14 and 16 mV, respectively (Fig. 7, A and B).

Component Currents of Late-Pregnant Myocytes

The development and decay of ILP1 and ILP2 were also exponential. Activation of both currents were voltage dependent; tau  for ILP1 was faster (10 ± 1 ms at +20 mV; 4 ± 0.4 ms at +70 ms; 20 myocytes) than tau  for ILP2 (18 ± 1 ms at +20 ms; 9 ± 1 ms at 70 mV; 20 myocytes), but neither rate was significantly different from the corresponding rate of nonpregnant myocytes. The activation of ILP3 was instantaneous. The decay of ILP1 could be described by two exponential terms; the faster term was voltage dependent and stabilized at ~200 ms, whereas the slower term was voltage independent at ~2.5 s. ILP2 and ILP3 showed little decay over 2.1 s.

The steady state activation and inactivation properties of ILP1, (Fig. 6 B), ILP2 (Fig. 6 C), and ILP3 (Fig. 6 D) are shown in Fig. 6 as filled symbols, and their Boltzmann distributions in broken lines, for comparison with those of nonpregnant myocytes. Their half-activation voltages and the associated slopes as well as their maximum conductances are given in Table I. The V-h relations in Fig. 6, B and C, were rescaled from Fig. 5 B, and the half-inactivation voltages and associated slopes are given in Table I. Regions of overlap with the activation curves are similar to those seen in nonpregnant myocytes.

Unlike nonpregnant myocytes, increasing [Ca2+]o to 30 mM caused no significant shifts in the activation curve of any of the component currents of late-pregnant myocytes (Fig. 7, C and D).

Among many similarities in the component currents of nonpregnant and late-pregnant myocytes, significant differences were found in three areas: maximum conductances of their C1 components (493 µS/cm2 for INP1 vs. 254 µS/cm2 for ILP1; P < 0.001 by t test); the steady state half-activation voltages of their C3 components (39.1 mV for INP3 vs. 63.4 mV for ILP3; P = 0.004); and their responses to raised Ca2+ concentrations in the bath. These differences underlie important characteristics of the whole-cell K+ currents (see DISCUSSION).

pharmacological responses of myometrial k+ psi eta alpha nu nu epsilon lambda sigma

As the total IK is separated into smaller units by different holding potentials, additional use of selective blocking agents may identify some individual channel types and reveal their contributions to the total current (Table II).

                              
View this table:
[in this window]
[in a new window]
 

Table II
Percent of Whole-Cell IK Susceptible to Blocking Agent

Tetraethylammonium Ion

Fig. 8 shows the typical actions of tetraethylammonium (TEA) on ILP1 and ILP2,3 of late-pregnant myocytes. At 0.5 mM, TEA appreciably reduced the average current (Fig. 8, A and B) as well as the current noise at all voltages (Fig. 8 B). Similar effects were seen in nonpregnant myocytes. The noisiness of the affected component and its stability over 2.1 s (see difference currents, Icontrol - ITEA, Fig. 8 C) suggest that only a large-conductance channel was blocked. In 2 mM or higher concentrations, the blocked current also contained an early decaying phase (Fig. 8 D), possibly attributable to additional channel types. Therefore, for differentiating channel types, we will focus on the effects of 0.5 mM TEA.

On average, the TEA-sensitive component in ILP1 amounted to 17% (ITEA/Icontrol = 0.83 ± 0.09, five myocytes), which contributed 11% of the total IK (0.17 × 0.67; see Fig. 5 B). On ILP2,3, the TEA-sensitive component represented 26% (ITEA/Icontrol = 0.74 ± 0.11, five myocytes). As it contained a residue of 8.3% of ILP1, the blocked fraction in the C2,3 components was 24%, which contributed 8% (0.24 × 0.33) of the total IK. Thus, the susceptible current(s) represented 19% of the total IK of late-pregnant myocytes (Table II).

In nonpregnant myocytes, the blocked fraction in INP1 was 36%, which contributed 21% (0.36 × 0.59) of the total IK. In INP2,3, the blocked fraction after correction for residual INP1 was 33%, contributing 14% (0.33 × 0.41) of the total current. In sum, the TEA-sensitive component constituted 35% of the total IK of nonpregnant myocytes (Table II).

Charybdotoxin

This peptidyl toxin from the scorpion, Leiurus quinquestriatus, blocks several Ca2+-activated K+ channels and also voltage-gated potassium channels (Miller et al., 1985; Garcia et al., 1995). It was tested on three nonpregnant and seven late-pregnant myocytes at 100 nM (IC50, 100 pM, Vasquez et al., 1989). On nonpregnant myocytes, charybdotoxin (ChTX) reduced the ITO (Fig. 9 A), the average current, and the current noise. The susceptible current(s) (as Icontrol - IChTX, Fig. 9, C and D) had three components: an ITO that peaked at ~3 ms and was already present at -30 mV; a noisy current in INP1 (at 30 and 50 mV, Fig. 9 A) that was inactivated at HP -50 mV (for eliciting INP2,3, Fig. 9 B); and another that appeared at voltages positive to 50 mV (Fig. 9 D). The blocked fraction in INP1 represented 24%, contributing 14% of the total current. In INP2,3, the blocked fraction less the residual INP1 was 18%, contributing 7% of the total. In sum, ChTX blocked 21% of the whole-cell IK of nonpregnant myocytes (Table II).

On late-pregnant myocytes (Fig. 9, E-H), the main effect of ChTX was a reduction of the average current (Fig. 9, E and F). Although outward currents were already evident at -30 to 0 mV, the susceptible current(s) did not appear till 10 mV, and increased with more positive voltages (Fig. 9 E). The blocked current had two components: an early part that peaked at ~10 ms, and a late part that had a noisiness and activation similar to those in nonpregnant myocytes (Fig. 9 G). In ILP2,3 (Fig. 9 F), the susceptible current rose gradually over ~25 ms, and did not decay over 230 ms (Fig. 9 H), but it differed from its counterpart in nonpregnant myocytes in emerging at a much less positive voltage of 10 mV. In ILP1, the blocked fraction averaged 9%, contributing 6% of the total IK. In ILP2,3, the blocked fraction after correction for residual ILP1 averaged 21%, contributing 7% of the total current. In sum, 13% of the whole-cell IK of late-pregnant myocytes were susceptible to ChTX (Table II).

Iberiotoxin

This peptidyl toxin from the scorpion, Buthus tamulus, is more potent (IC50 approx  25 pM) and more specific than ChTX for the large-conductance Ca2+-activated K+ channel (Galvez et al., 1990). It was tested at 1 nM concentration on four nonpregnant and four late-pregnant myocytes. Fig. 10 shows the typical effects on two nonpregnant myocytes (Fig. 10, A-G) and two late-pregnant myocytes (Fig. 10, H-K). The effects were qualitatively similar: it reduced the average current and the current noise (Fig. 10 G). The predominant susceptible current was nondecaying, but sometimes an early decaying component was seen (Fig. 10 C). The effects on ITO differed from those of ChTX: the ITO at small depolarizations were minimally affected, but ITO at more positive voltages were blocked, indicating that myometrial ITO originated from more than a single channel type. On INP1, the blocked fraction averaged 17% (four myocytes), contributing 10% of the total IK. On INP2,3, the blocked fraction after correction for residual INP1 averaged 48%, contributing 20% of the total IK. In sum, 30% of the whole-cell IK of nonpregnant myocytes were susceptible to iberiotoxin (IbTX; Table II).

On some late-pregnant myocytes, IbTX had no effect (Fig. 10 H). On average, the blocked fraction of ILP1 averaged 8%, comprising 5% of the total current. On ILP2,3, the blocked fraction after correction for residual ILP1 averaged 39%, contributing 13% of the total current. In sum, 18% of the whole-cell IK of late-pregnant myocytes were susceptible to IbTX (Table II).

Apamin

This toxin from the venom of honey bees blocks a small-conductance K+ channel that is sensitive to Ca2+, but not to voltage (Romey et al., 1984; Blatz and Magleby, 1986). It (100 nM) was tested on one nonpregnant and five late-pregnant myocytes. On the former, it had no detectable effects. On the latter, it had no effect on ILP1 (Iapamin/Icontrol = 1.00 ± 0.02, five myocytes), but blocked 15% of ILP2,3 (Iapamin/Icontrol = 0.85 ± 0.02), which should affect 5% of the total IK.

4-Aminopyridine

Three concentrations of 4-aminopyridine (4-AP), 0.4, 1, and 5 mM, were tested on two nonpregnant and six late-pregnant myocytes (Fig. 11). Their actions were similar in both types of myocytes, and they differed from those of TEA, ChTX, or IbTX: (a) the noisy current fluctuations were unaffected (Fig. 11, B and F); (b) it slowed the activation of ILP2,3 (Fig. 11, F and G), resulting in a seemingly greater effect at 150 ms (I4-AP/ Icontrol = 0.38 ± 0.03, six myocytes) than at 2.1 s (I4AP/ Icontrol = 0.78 ± 0.03); and (c) it hastened the decay of the TEA-insensitive component in ILP1. These effects occurred with all three concentrations, being most marked in 5 mM. On ILP3, 5 mM 4-AP had no effect. In ILP1, the blocked fraction averaged 48%, comprising 32% of the total IK. After correction for residual ILP1, the blocked fraction in ILP2,3 averaged 56%, comprising 18% of the total current. In sum, 50% of the whole-cell IK of late-pregnant myocytes were susceptible to 4-AP (Table II).

Significantly, in nonpregnant myocytes, the ITO, peaking at ~3 ms, was not preferentially blocked (Fig. 11 A; also dose-response relations in Fig. 11 H). The blocked fraction of INP1 averaged 73%, comprising 43% of the total outward current. After correction for residual INP1, the blocked fraction of INP2,3 averaged 32%, comprising 13% of the total current. In sum, 56% of the whole-cell IK of nonpregnant myocytes were susceptible to blockade by 4-AP (Table II).

alpha -Dendrotoxin

This member of a group of peptidyl toxins from the venom of mamba snakes (Dendroaspis augusticeps) blocks a gradually activating and slowly decaying voltage-gated channel of small conductance that shows little outward rectification (see Dreyer, 1990). It was tested on five nonpregnant and four late-pregnant myocytes at 200 and 400 nM. On the former, alpha -dendrotoxin (DTX) had no effect (Fig. 12, A and B). On late-pregnant myocytes, DTX did not reduce current fluctuations and was more effective in blocking ILP2,3 (IDTX/Icont = 0.60 ± 0.10, four myocytes) than ILP1 (IDTX/Icont = 0.90 ± 0.10; Fig. 12, C and D). Thus, the fractions blocked were 37% (after correction for residual ILP1) and 10%, respectively, contributing 12 and 7% of the total IK, for a sum of 19% (Table II; observed IDTX/Icontrol for whole-cell IK = 0.82 ± 0.02; four myocytes).

Mast-Cell Degranulating Peptide

Mast-cell degranulating peptide (MCDP), a peptidyl toxin from honey bee venom, blocks the same class of delayed rectifier as DTX (Stansfeld et al., 1987; Brau et al., 1990; Dreyer, 1990). It was applied to four late-pregnant myocytes at 100 nM. There was little effect on ILP1. Its effects were confined to the ILP2,3, reducing the average current (IMCDP/Icontrol = 0.89 ± 0.03) without affecting current fluctuations. The deduced effect on the whole-cell IK is 3.6% (Table II; observed IMCDP/Icont = 0.96 ± 0.02; four myocytes).

Table II summarizes the effects of the various agents. Allowing for some overlapping actions, a combination of ChTX, IbTX, and 4AP on nonpregnant myocytes, and additionally of apamin and DTX on late-pregnant myocytes, blocked all outward currents. The data show (a) KCa currents constitute a smaller fraction of the total outward current in late-pregnant than in nonpregnant myocytes, and (b) DTX-susceptible Kv currents are present in late-pregnant but not in nonpregnant myocytes.

single-channel observations

To resolve an apparent contradiction between the presence of KCa channels in late-pregnant uterine myocytes and the Ca2+ insensitivity of their whole-cell IK, we conducted some single-channel studies on detached inside-out patches of the surface membrane, focussing on the large-conductance Ca2+-activated K+ (maxi-K) channel. As reference, we used patches from taenia coli myocytes that contained abundant maxi-K channels (Hu et al., 1989; Fan et al., 1993).

In patches from taenia coli myocytes, openings of single K+ channels, often in multiples, were seen in every patch, yielding an average of 2.7 channels per patch. In these, the 150-pS channel openings predominated (>95%). In patches from late-pregnant uterine myocytes, single channel activities were rarer; 8 of 51 (15.7%) randomly made patches showed no openings of any type, and in many patches only one channel was present, yielding an average of 1.8 channels per patch. In them, single-channel activities were also more complex. Of 92 single channels, the frequency of occurrence of various types (by their unitary conductance and charge-carrier) were: 140-pS K+ channels, 60.8%; 50-pS K+ channels, 7.6%; 20-pS K+ channels, 16.3%; 400-pS Cl- channels, 15.2%. However, when by chance a patch contained both small- and large-conductance channels, the small-conductance channels were usually much more active than the large-conductance channels, as evident in Fig. 13, A and B.


View larger version (25K):
[in this window]
[in a new window]
 
Fig. 13.   Relative activities of small and large-conductance K+ channels in membrane patch from late-pregnant uterine myocyte. (A) Detached inside-out patch from 18-d pregnant uterine myocyte. Holding potential +40 mV. Pipette solution (facing outside of membrane, mM): 135 NaCl, 5.4 KCl, 1 CaCl2, 1 MgCl2, 10 HEPES, 5 glucose. Bath solution (facing inside of membrane, mM): 135 KCl, 0.6 EGTA, 0.1 CaCl2 (pCa = 8), 10 HEPES. This patch has both small- and large-conductance channels, infrequently encountered in uterine myocyte patches. Closed state (c) marked at left margin. Dotted lines indicate different open levels: first level is for small-conductance channel, second level is for large-conductance channel, third level is for simultaneous openings of small and large channels. Unit conductance for small channel is 41 pS; for large channel, 180 pS. (B) Activity histogram of channels in A. Abscissa in 0.1 pA bins; ordinate in log scale, total data points, each representing 150-µs duration (in a 16-s continuous recording). Peak a represents closed state, b a small-conductance channel alone, c a large-conductance channel alone, and d a small and large channel simultaneously. Po for the large channel is 0.007 and for the small channel is 0.15 (21× higher; see text for other details).

The myometrial maxi-K channels exhibited readily detectable activities at approximately -30 mV, and the current-voltage (i-V) relation in asymmetric K+ distribution (Ki/Ko = 5.4/135) showed significant outward rectification. They had a unitary conductance of 139 ± 3 pS (at 0 mV; n = 24), and, by extrapolation of the -30 to 0 mV segment of the i-V curve, a zero-current voltage at -83 mV (expected Nernst potential, -82 mV).

Influence of Voltage and [Ca2+]i on Po of Maxi-K+ Channels

Comparing taenia and myometrial patches, there are differences in the open probability of the maxi-K channels, voltage-Po relations, and the sensitivity of Po to internal Ca2+ concentrations. Fig. 14, A and B, shows the V-Po relations of two representative channels, one from a taenia myocyte and the other from a uterine myocyte, at pCa's 7 and 8. Fig. 14 C summarizes such data from six taenia channels and nine myometrial channels. Several features are readily apparent. (a) The slopes of the curves (k), representing that the logarithmic voltage dependence of Po is shallower for the myometrial channel (10.5 ± 0.9 mV at pCa 8; 12.2 ± 1.6 mV at pCa 7) than for the taenia channel (7.6 ± 0.6 mV at pCa 8; 8.6 ± 0.7 mV at pCa 7). By t test, the difference in pCa 8 is significant (P = 0.05), whereas the difference in pCa 7 is not (P = 0.12). (b) The voltage at which Po = 0.5 (Vh; i.e., when a channel is equally likely to be open as closed) is more positive for the myometrial channel (86.8 ± 9.1 mV at pCa 8; 68.3 ± 9.1 mV at pCa 7) than for the taenia channel (49.7 ± 5.4 mV at pCa 8; 24.1 ± 5.2 mV at pCa 7). The difference for either pCa is significant (P = 0.004 for pCa 8, and 0.012 for pCa 7). (c) The negative shift of Vh when pCa is changed from 8 to 7 is less in the myometrial channel (18 mV) than in the taenia channel (26 mV).


View larger version (44K):
[in this window]
[in a new window]
 
Fig. 14.   Voltage-open probability relations of maxi-K channels from taenia coli myocyte and late-pregnant uterine myocyte, and effects of [Ca2+]i on them. (A and B) Data from representative individual patch for illustration. (C) Summary of data. In A and B, solid curves are Boltzmann distributions: Po = [1 + exp(Vh - V)/ k]-1, where Vh is voltage at which Po = 0.5, and k is logarithmic voltage sensitivity. Filled symbols for pCa 8; hollow symbols for pCa 7. (A) For taenia coli channel, Vh and k are, respectively, 63.2 and 7.9 mV for pCa 8, and 35.4 and 8.9 mV for pCa 7. (B) For late-pregnant myometrial channels, they are, respectively, 76.3 and 9.1 mV for pCa 8, and 60.3 and 10.4 mV for pCa 7. Differences: in myometrial channel, Vh is more positive, k is shallower, and negative shift of Vh on increasing [Ca2+]i is less. (C) Average Po-V relations of late-pregnant maxi-K channel compared with those of taenia coli channel. Curves are computed Boltzmann distributions based on mean data of Vh and k obtained individually from six taenia coli patches and nine myometrial patches. Each curve is identified by average Vh value used; triangles for myometrial channels, circles for taenia coli channels. Filled symbols for pCa 8, hollow symbols for pCa 7. See text for data.

From Fig. 14 C, it is readily apparent that within the physiological range of voltages (-40 to +30 mV), the open probability at a fixed pCa in the myometrial maxi-K channel is only ~0.05-0.1 that of the taenia channel.

    DISCUSSION
Top
Abstract
Introduction
Methods
Results
Discussion
References

Confusion abounds in our knowledge of myometrial K+ currents, possibly because of concurrent expressions of multiple types of channels and labile combinations of channel types engendered by hormonal influences. Previous studies centered on single states of the myometrium (Mironneau and Savineau, 1980; Miyoshi et al., 1991; Piedras-Renteria et al., 1991; Inoue et al., 1993), or identified tissue-cultured material with freshly dissociated myocytes (Toro et al., 1990; Erulkar et al., 1994). As whole-cell K+ currents were generally treated in their entirety, variance could be expected between extant claims and the present results. Thus, the prominence of a Ca2+-activated K+ current in multicellular preparations of late-pregnant myometrium (Mironneau and Savineau, 1989) is inconsistent with the Ca2+ insensitivity of myocytes from such preparations (Figs. 2 and 3; also Kao et al., 1989; Miyoshi et al., 1991; Inoue et al., 1993). A transient outward current in late-pregnant myocytes surmised solely on the basis of 4-AP action (Inoue et al., 1993) may have resulted from an unobserved slowing of activation of IK by 4-AP (see Fig. 11, F and G), because such a current was not seen in late-pregnant myocytes. The difficulties of equating tissue-culture material with freshly dissociated myocytes is exemplified by the fact that three K+ currents in freshly dissociated nonpregnant myocytes (Piedras-Renteria et al., 1991) were very different from those seen by the same investigators in tissue-cultured material (Toro et al., 1990). They also lack counterparts in the present study, not least because they could not be recorded with pipette solutions containing Ca2+ buffers (contrast also Miyoshi et al., 1991). The ITO of the present study, half inactivated at -77 mV and half activated at 5 mV (Fig. 6 A) is clearly different from an incompletely characterized transient K+-current (Kt) that was half activated at 22 mV (Piedras-Renteria et al., 1991), and another seen in tissue-cultured material that was half inactivated at -48 mV (Erulkar et al., 1994).

Although the whole-cell approach used in this study cannot identify native K+ channels with cloned K+ channels (because of accessory unit influence or heteromultimeric assembly), the paradigm used has sorted out more concurrent K+ currents in smooth myocytes than had been accomplished before. The combined sifting with holding potentials and blocking agents also recognized the appropriate roles of some channels that would have been masked in a whole-cell current approach. In uterine myocytes, the K+ currents are due to voltage-gated (Kv) currents and their related Ca2+-activated K+ (KCa) currents. No inwardly rectifying K+ currents were detected.

By their noninactivating nature, noisiness and susceptibility to IbTX (Fig. 10 G), 85-90% of the C3 currents are attributed to large-conductance KCa channels, a surmise consistent with their nonresponsiveness to 4-AP. The C2 currents contained several types of KCa currents and Kv currents: KCa currents of the small- or intermediate-conductance varieties were recognized by their susceptibility to ChTX and apamin, and Kv currents by their susceptibility to 4-AP, DTX, and MCDP. The C1 currents contained the most diverse constituents of both Kv and KCa types. Of the Kv currents, because of vast differences in their steady state gating properties (Fig. 6), the ITO and the delayed-rectifier currents probably originated in different channels rather than in a single channel type with different accessory-unit modification of their inactivation kinetics. That 4-AP had no preferential effect on the ITO suggested that the native ITO channel(s) might be closer to rKv 1.4 than to rKv 3.3 or rKv 3.4 (see Chandy and Gutman, 1995). In late-pregnant myocytes, the gating and pharmacological properties of the native K+ channels resembled those of cloned rKv 1.1, 1.2, 1.6 channels (see Chandy and Gutman, 1995).

Changes in Myometrial K+ Currents During Pregnancy

Among many similarities in the K+ currents of nonpregnant and late-pregnant myocytes, three differences are particularly notable: (a) ITO, often present in nonpregnant myocytes, is absent in late-pregnant myocytes; (b) K+ currents of late-pregnant myocytes are insensitive or much less sensitive than those of nonpregnant myocytes to changes in intracellular or extracellular Ca2+; and (c) some delayed-rectifier currents are seen only in late-pregnant myocytes.

As ITO regulates the membrane potential during burst spike discharges (Conner and Stevens, 1971), its absence in late pregnancy removes a constraint on repetitive action potentials that occur with greater frequencies as term approaches. Several factors underlie the relative Ca2+ insensitivity of late-pregnant myocytes. Firstly, there are differences in screenable surface negative charges (Frankenhauser and Hodgkin, 1957), whereas voltage-activation relations of nonpregnant myocytes were shifted 15 mV to the positive by elevated [Ca2+]o, those of late-pregnant myocytes were unaffected (Fig. 7). Such a charge-screening effect must also influence the voltage-inactivation relations. Thus, for nonpregnant myocytes held at -50 mV, a 15-mV shift would increase the available fraction of ITO from ~1% in 1 mM Ca2+ (Fig. 6 A) to ~20% in 30 mM Ca2+, enough to largely account for a revival of an ITO that had been inactivated (Fig. 2). Other factors involve more direct changes in K+ channel types. Pharmacological responses indicate that as pregnancy progressed towards term, maxi-K (KCa) channels are replaced by smaller-conductance delayed rectifier (Kv) channels to express whole-cell K+ currents. This change accounts for the difference between the noisy and outwardly rectifying current of nonpregnant myocytes and the rather smooth current with little rectification of the late-pregnant myocytes.

The lowered expression of maxi-K channels can result from a reduced density and/or altered conditions for their expression. A reduced density is suggested by the different responses of the IK of nonpregnant and of late-pregnant myocytes to photolysis-induced increase of [Ca2+]i (Fig. 4). The possibility of altered conditions of expression is shown in the V-g relations of the C3 currents (Fig. 6 D; 39 mV for nonpregnant myocytes and 63 mV for late-pregnant myocytes), which are mostly due to IbTX-sensitive large-conductance KCa channel(s) (Fig. 10 G). Single maxi-K channels from late-pregnant myocytes have a half-open probability in pCa 7 of 68 mV (Fig. 14). They are also less sensitive to Ca2+ than similar channels in taenia coli myocytes, which express them abundantly. Limiting the expression of maxi-K channels could increase myometrial excitability by setting the resting potential positive to the potassium equilibrium potential, and by decreasing the resting membrane conductance and thereby lowering the current needed to trigger action potentials. Fig. 6 D shows that, in the physiological range of voltages, differences in the fractional activation of these currents are substantial. For instance, at -20 mV (near the spike threshold), the fractional activation is 0.03 for nonpregnant myocytes and 0.005 for late-pregnant myocytes; at 20 mV (near the peak of action potentials), these fractions are 0.26 and 0.08, respectively.

In conclusion, as pregnancy progresses towards term, myometrial maxi-K channels lose functional importance through a combination of factors that include a change in surface negative charges, a reduction in density, a positive shift of voltage-activation relation, and a lowered sensitivity to Ca2+. In concert with a suppression of ITO and an increased expression of a fast Na+ channel (Yoshino et al., 1997), these changes facilitate repetitive spike discharges for the needs of parturition.

    FOOTNOTES

Address correspondence to Peter N. Kao, M.D., Ph.D., Pulmonary and Critical Care Medicine, Stanford University Medical Center, Stanford, CA 94305-5236. Fax: 650-725-5489; E-mail: peterkao{at}leland.stanford.edu

Original version received 18 June 1998 and accepted version received 21 September 1998.

dagger    Dr. C.Y. Kao died on May 26, 1998.
   This paper is dedicated to Chien Yuan Kao, M.D., who died unexpectedly on May 26, 1998. My father introduced me to scientific research and medicine and served as my most trusted mentor and closest friend throughout my life (P.N. Kao). The C.Y. Kao Memorial Medical Student Research Scholarship Fund has been established to support training in basic science investigation, and is administered at the Department of Pharmacology, State University of New York Health Sciences Center.
   The work described was supported by grants from the National Institutes of Health (HD00378 and DK39371).
    Abbreviations used in this paper

4-AP, 4-aminopyridine; ChTX, charybdotoxin; DTX, alpha -dendrotoxin; HP, holding potential; i-V, current- voltage; IbTX, iberiotoxin; ITO, transient outward current; MCDP, mast-cell degranulating peptide; TEA, tetraethylammonium; V-g, voltage-conductance; V-h, voltage-steady state inactivation.

    REFERENCES
Top
Abstract
Introduction
Methods
Results
Discussion
References

1. Amman, D. 1986. Ion Selective Microelectrodes. Springer Verlag GmbH & Co. Berlin, Germany. 109-207.
2. Blatz, A.L., and K.L. Magleby. 1986. Single apamine-blocked Ca2+-activated K+ channels of small conductance in cultured rat skeletal muscle. Nature. 323: 718-720 [Medline].
3. Brau, M.E., F. Dreyer, P. Jones, H. Repp, and W. Vogel. 1990. A K+ channel in Xenopus nerve fibers selectively blocked by bee and snake toxins: binding and voltage-clamp experiments. J. Physiol. (Camb.) 420: 365-385 [Abstract].
4. Chandy, K.G., and G.A. Gutman. 1995. Voltage-gated potassium channel genes. In Handbook of Receptors and Channels, Ligand and Voltage-Gated Ion Channels. R.A. North, editor. CRC Press. Boca Raton, FL. 1-71.
5. Conner, J.A., and C.F. Stevens. 1971. Voltage clamp studies of a transient outward membrane current in gastropod neural somata. J. Physiol. (Camb.). 213: 21-30 [Medline].
6. Dreyer, F.. 1990. Peptide toxins and potassium channels. Rev. Physiol. Biochem. Pharmacol. 115: 93-136 [Medline].
7. Erulkar, S.D., J. Rendt, R.D. Nori, and B. Ger. 1994. The influence of 17-oestradiol on K+ currents in smooth muscle cells isolated from immature rat uterus. Proc. R. Soc. Lond. B Biol. Sci. 256: 59-65 [Medline].
8. Fan, S.F., S.Y. Wang, and C.Y. Kao. 1993. The transduction pathway of isoproterenol activation of the Ca2+-activated K+ channel in guinea pig taenia coli myocyte. J. Gen. Physiol. 102: 257-275 [Abstract].
9. Frankenhauser, B., and A.L. Hodgkin. 1957. The role of calcium on the electrical properties of squid axon. J. Physiol. (Camb.) 137: 218-244 .
10. Galvez, A., G. Gimenez-Gallego, J.P. Reuben, L. Roy-Contacin, P. Feigenbaum, G.J. Kaczorowski, and M.L. Garcia. 1990. Purification and characterization of a unique potent peptidyl probe for the high conductance calcium-activated potassium channel from venom of the scorpion Buthus tamulus. J. Biol. Chem. 265: 11083-11090 [Abstract/Free Full Text].
11. Garcia, M.L., H.G. Knaus, P. Munujos, R.S. Slaughter, and G.J. Kaczorowski. 1995. Charybdotoxin and its effects on potassium channels. Am. J. Physiol. 269: C1-C10 [Abstract/Free Full Text].
12. Gurney, A.M., R.Y. Tsien, and H.A. Lester. 1987. Activation of a potassium current by rapid photochemically generated step increase of intracellular calcium in rat sympathetic neurons. Proc. Natl. Acad. Sci. USA 84: 3496-3500 [Abstract].
13. Hille, B. 1992. Ionic Channels of Excitable Membranes. 2nd ed. Sinauer Associates, Inc. Sunderland, MA. p. 115.
14. Hu, S.L., Y. Yamamoto, and C.Y. Kao. 1989a. The Ca2+-activated K+ channel and its functional roles in smooth muscle cells of the guinea pig taenia coli. J. Gen. Physiol. 94: 833-847 [Abstract].
15. Hu, S.L., Y. Yamamoto, and C.Y. Kao. 1989b. Permeation, selectivity, and blockade of the Ca2+-activated potassium channel of the guinea pig taenia coli myocyte. J. Gen. Physiol 94: 849-862 [Abstract].
16. Inoue, Y., K. Shimamura, and N. Sperelakis. 1993. Forskolin inhibition of K+ current in pregnant rat uterine smooth muscle cells. Eur. J. Pharmacol. 240: 169-176 [Medline].
17. Jan, L.Y., and Y.N. Jan. 1997. Cloned potassium channels from eukaryotes and prokaryotes. Annu. Rev. Neurosci. 20: 91-123 [Medline].
18. Kao, C.Y., and J.R. McCullough. 1975. Ionic currents in the uterine smooth muscle. J. Physiol. (Camb.). 246: 1-36 [Abstract].
19. Kao, C.Y., and M.J. Siegman. 1963. Nature of electrolyte exchange in isolated uterine smooth muscle. Am. J. Physiol. 205: 674-680 .
20. Kao, C.Y., M. Wakui, S.Y. Wang, and M. Yoshino. 1989. The outward current of the isolated rat myometrium. J. Physiol. (Camb.). 418: 20 .
21. Kaplan, J.H.. 1990. Photochemical manipulation of divalent cation levels. Annu. Rev. Physiol. 52: 897-914 [Medline].
22. Miller, C., E. Moczydlowski, R. Lattore, and M. Philippa. 1985. Charybdotoxin, a potent inhibitor of single Ca2+-activated K+ channels from mammalian skeletal muscle. Nature. 313: 316-318 [Medline].
23. Mironneau, J., and J.P. Savineau. 1980. Effects of calcium ions on outward membrane currents in rat uterine smooth muscle. J. Physiol. (Camb.). 302: 411-425 [Abstract].
24. Miyoshi, H., T. Urabe, and A. Fujiwara. 1991. Electrophysiological properties of membrane currents in single myometrial cells isolated from pregnant rats. Pflügers Arch 419: 386-393 [Medline].
25. Parkington, H.C., and H.A. Coleman. 1990. The role of membrane potential in the control of uterine activity. In Uterine Function. M.E. Carsten and J. Miller, editors. Plenum Publishing Corp. New York. p. 219.
26. Piedras-Renteria, E., L. Toro, and E. Stefani. 1991. Potassium currents in freshly dispersed myometrial cells. Am. J. Physiol. 251: C278-C284 .
27. Romey, G., M. Hugues, H. Schmid-Antonmarchi, and M. Lazdunski. 1984. Apamin: a specific toxin to study a class of Ca2+-activated K+ channels. J. Physiol. (Paris). 79: 259-264 [Medline].
28. Suput, D., M. Yoshino, S.Y. Wang, and C.Y. Kao. 1989. Ionic currents in freshly dissociated rat myometrial cells. FASEB J. 3: A254 .
29. Stansfeld, C.E., S.J. Marsh, D.M. Parcej, J.O. Dolly, and D.A. Brown. 1987. Mast cell degranulating peptide and dendrotoxin selectively inhibit a fast-activating potassium current and bind to common neuronal proteins. Neuroscience. 23: 893-902 [Medline].
30. Sui, J.L., and C.Y. Kao. 1997. Role of outward potassium currents in the action potential of guinea pig ureteral myocytes. Am. J. Physiol. 273: C962-C972 [Abstract/Free Full Text].
31. Toro, L., E. Stefani, and S. Erulkar. 1990. Hormonal regulation of potassium currents in single myometrial cells. Proc. Natl. Acad. Sci. USA 87: 2892-2895 [Abstract].
32. Vasquez, J., P. Feigenbaum, G.M. Katz, V.F. King, J.P. Reuben, L. Roy-Contancin, R.S. Slaughter, G.J. Kaczorowski, and M.L. Garcia. 1989. Characterization of high-affinity binding sites for charybdotoxin in sarcolemmal membranes from bovine aortic smooth muscle. J. Biol. Chem. 264: 20902-20909 [Abstract/Free Full Text].
33. Wang, S.Y., M. Yoshino, J.L. Sui, and C.Y. Kao. 1996. Pregnancy and K+ currents of freshly dissociated rat uterine myocytes. Biophys. J. 70: A396 .
34. Yamamoto, Y., S.L. Hu, and C.Y. Kao. 1989. Outward current in single smooth muscle cells of the guinea pig taenia coli. J. Gen. Physiol. 93: 551-564 [Abstract].
35. Yoshino, M., S.Y. Wang, and C.Y. Kao. 1989. Ionic currents in smooth myocytes of the pregnant rat uterus. J. Gen. Physiol. 94: 38a .
36. Yoshino, M., S.Y. Wang, and C.Y. Kao. 1997. Sodium and calcium inward current in freshly dissociated smooth myocytes of rat uterus. J. Gen. Physiol. 110: 565-577 [Abstract/Free Full Text].

Copyright © 1998 by The Rockefeller University Press.
0022-1295/98/12/737/20 $2.00