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Departments of Anesthesiology, Physiology and Biophysics, Surgery, and Endocrinology, Mayo Foundation, Rochester 55905; and Departments of Veterinary PathoBiology and Pediatrics, University of Minnesota, St. Paul, Minnesota 55108
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ABSTRACT |
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 Top
 Abstract
 Introduction
Methods
Results
Discussion
References
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Acute estrogen
administration relaxes vascular smooth muscle by decreasing
intracellular Ca2+ concentration
([Ca2+]i).
In the present study, we examined the hypothesis that this reduction in
[Ca2+]i
is mediated in part by enhanced
Ca2+ efflux. Coronary artery
smooth muscle cells were isolated from gonad-intact, sexually mature
female pigs. The
[Ca2+]i
response to endothelin-1 was measured using fluo 3 and confocal microscopy. 17
-Estradiol
(E2), but not 17
-estradiol
or triamcinolone acetonide, caused a concentration-dependent
(IC50 = 10 nM) decrease in the
[Ca2+]i
response to endothelin-1. This decrease was blocked by the specific
estrogen receptor antagonist ICI-182780. Under conditions in which
Ca2+ influx and sarcoplasmic
reticulum Ca2+ reuptake were
blocked, E2 still decreased
[Ca2+]i.
The response was blocked by extracellular lanthanum. These data
indicate that E2 decreases
[Ca2+]i
in coronary artery smooth muscle by affecting
Ca2+ efflux via a
receptor-mediated mechanism.
vasodilation; endothelin; receptor; calcium adenosine 5'-triphosphatase
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INTRODUCTION |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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ACUTE ADMINISTRATION of estrogens relaxes vascular smooth muscle, causing a reduction in vascular resistance and an increase in blood flow (3, 5, 8, 9, 16, 19, 21, 25, 30). The rapid relaxation of vasomotor tone induced by estrogens is likely mediated through nongenomic effects (for review, see Ref. 2) and probably involves estrogen receptors (2, 11, 20). However, despite considerable evidence for acute, nongenomic effects of estrogen on vascular tissue, the mechanisms underlying these effects are not completely understood.
Estrogen-induced relaxation of vascular smooth muscle involves a
reduction in intracellular Ca2+
concentration
([Ca2+]i)
(15, 19). One demonstrated mechanism for this effect is a decrease in
Ca2+ influx (8, 9, 14). However, a
reduction in
[Ca2+]i
induced by estrogens may also result from an increase in
Ca2+ efflux, an inhibition of
Ca2+ release from the sarcoplasmic
reticulum (SR), or an increase in SR
Ca2+ reuptake. Therefore, the
purpose of the present study was to examine whether estrogens
[17-estradiol
(E2)] affect
Ca2+ efflux and SR
Ca2+ release in coronary artery
smooth muscle.
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METHODS |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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Animals. Ten sexually mature female Yorkshire pigs (at least 6 mo of age) were obtained from a local supplier. Animals were anesthetized with ketamine (8 mg/kg) and xylazine (12 mg/kg), and their hearts were removed. The three main coronary arteries (right and left circumflex and left anterior descending arteries) were removed and placed in oxygenated modified Krebs-Ringer bicarbonate solution at 4°C. Blood samples were also drawn to verify hormonal status using plasma concentrations of estrogen and progesterone.
All animal surgical and care procedures were approved by the Institutional Animal Care and Use Committee of the Mayo Clinic and were in strict accordance with the American Physiological Society animal care guidelines.Immunocytochemical detection of estrogen receptors. Freshly dissociated coronary artery smooth muscle cells were fixed in 4% paraformaldehyde in 0.1 M phosphate buffer and stained for 2-3 h with a polyclonal antibody to the estrogen receptor (Research Biochemicals; 1:2,000 dilution in phosphate buffer). After staining with the primary antibody was completed, the sections were washed in phosphate buffer and reacted with a 1:1,000 Cy3-conjugated donkey anti-rabbit IgG secondary antibody. The fluorescently labeled coronary artery smooth muscle cells were visualized using a Bio-Rad MRC500 confocal microscope equipped with an argon-krypton laser. The 568-nm laser line was used to excite the Cy3, and the emissions were collected using a 590-nm long-pass filter.
Cell preparation for Ca2+ imaging. The procedures for dissociation of single porcine coronary artery smooth muscle cells have been described previously (10). Briefly, the endothelium was removed and the tissue was minced thoroughly in Hanks' balanced salt solution (HBSS) buffered with 10 mM HEPES (pH 7.4; Life Technologies, Gaithersburg, MD). The tissue was incubated first in 20 U/ml papain and 2,000 U/ml DNase (Worthington Biochemical, Freehold, NJ) and subsequently in 1 mg/ml type IV collagenase and 0.1 mg/ml elastase (Worthington). Single cells were released by trituration, centrifugation, and resuspension in minimum essential medium with 10% fetal calf serum. The cells were plated on glass coverslips coated with Cell-Tak (Collaborative Biomedical Products, Bedford, MA) and incubated for 1-2 h in a 5% CO2 incubation chamber at 37°C. Cells were used within 4 h after dissociation. No time-dependent changes were observed in the gross morphology of the cells that were used for the experimental protocols. Exclusion of the dye trypan blue was used to assess cell viability just after dissociation (>90% of all cells). An anti-smooth muscle myosin antibody (Sigma Immunochemicals, St. Louis, MO) was used to estimate the relative proportion of smooth muscle myocytes (immunoreactive) and fibroblasts (50:1).
Each coverslip was washed with HBSS and incubated for 30-45 min at 37°C in 5 µM fluo 3-AM (Molecular Probes, Eugene, OR). The coverslip was then washed briefly in HBSS and mounted on an open slide chamber (RC-25F, Warner Instruments, Hamden, CT) mounted on the stage of a Nikon Diaphot inverted microscope. The chamber was perfused at 2-3 ml/min at room temperature.Real-time Ca2+ imaging. An Odyssey XL real-time confocal system (Noran Instruments, Middleton, WI) attached to the Nikon Diaphot and equipped with an argon-krypton laser was used to visualize fluo 3-loaded coronary artery smooth muscle cells (18). An Olympus ×40/1.3 oil-immersion objective lens was used to visualize the cells. Image size was set to 640 × 480 pixels, and pixel area was calibrated using a stage micrometer (0.063 µm2/pixel). A fixed combination of laser intensity (20% of maximum) and photomultiplier gain (1,700 from a maximum of 4,096) was set a priori to ensure that pixel intensities within regions of interest ranged between 25 and 255 gray levels across different experimental protocols. Dye bleaching was kept to a minimum by maintaining laser intensity below 3 mW. Continued exposure to the laser did not exceed 3 min. With the use of these precautions, dye bleaching was estimated to be <5% over a 3 min period.
The Odyssey confocal system is controlled by a Silicon Graphics workstation and is capable of acquiring 480 frames/s. In preliminary studies on fluo 3-loaded coronary artery smooth muscle cells, it was determined that an acquisition rate of 30 frames/s was sufficient to measure the changes in [Ca2+]i during various protocols without frequency aliasing. Therefore, image acquisition was limited to 30 frames/s. When necessary, image noise was reduced by acquiring at 60 or 120 frames/s with frame averaging. The sampling time for any pixel was 100 ns. A region of the coverslip containing at least 15-20 coronary artery smooth muscle cells was selected, and a region-of-interest software tool was used to define regions within the boundaries of individual cells. Each region of interest had a fixed dimension of 10 × 10 pixels (6 µm2). The optical section thickness for the ×40 lens was set to 1 µm by controlling the confocal slit size. Therefore, Ca2+ measurements were obtained from a volume of 6 µm3. The fluorescence intensity of fluo 3 was calibrated for Ca2+ concentrations as described previously (18). At fixed settings of laser intensity and photomultiplier gain, fluo 3-loaded coronary artery smooth muscle cells were exposed to A-23187 (Ca2+ ionophore) at varying levels of extracellular Ca2+ ranging from 0 (HBSS with EGTA) to 10 µM. Exposure to the ionophore at each extracellular Ca2+ concentration was limited to ~1 min to ensure that other Ca2+ handling mechanisms such as mitochondria and SR did not compensate for the ionophore-induced Ca2+ influx and thus confound the calibration. Furthermore, fluo 3 is also capable of being incorporated into the mitochondria and nucleus with continued exposure. Accordingly, to ensure that the fluo 3 signal represented cytosolic Ca2+ only, the total duration of the calibration protocol was minimized. Based on a calibration curve constructed from the gray level values of fluorescence intensities at different Ca2+ concentrations, the average gray level within a region of interest was converted to nanomoles per liter of Ca2+.Assessment of cell viability. After each experiment, coronary artery smooth muscle cells on at least one coverslip per animal (~80 cells) were evaluated for the exclusion of trypan blue. These cells were exposed to the confocal laser for varying periods of time ranging from <3 min to repeated exposures across a 30-min period. The exclusion of trypan blue in these cells confirmed that laser exposure did not injure the cells. In a subset of these cells (20 cells), the effect of prolonged laser exposure (three 3-min exposure periods separated by 5 min) on baseline [Ca2+]i level was evaluated. Baseline [Ca2+]i was found to vary <5% across this entire period. In another subset of cells (15 cells), the reproducibility of the [Ca2+]i response to 5 mM caffeine was evaluated over a 20-min period. The average coefficient of variation for the [Ca2+]i response to caffeine in these cells was 6.5%.
[Ca2+]i response to endothelin-1. The [Ca2+]i response of coronary artery smooth muscle cells was measured to increasing concentrations of endothelin-1 (0.1, 1, 10, and 100 nM and 1 µM). Because tachyphylaxis is a well-known effect with endothelin-1, multiple-agonist exposures for the same cell were not possible. Instead, sets of coronary artery smooth muscle cells were exposed to only one endothelin-1 concentration, and the average response was determined.
Effect of estrogens on endothelin-1-induced elevation of
[Ca2+]i.
Cells were exposed to 100 nM endothelin-1, and an elevation in
[Ca2+]i
was confirmed. When
[Ca2+]i
had reached a steady-state level (2-3 min), the cells were exposed
to solvent (ethanol 10 nM), E2
(0.1 nM to 10 µM), 17-estradiol (E2; 10 nM, the biologically
inactive form of estradiol), or triamcinolone acetonide (10 nM; a
synthetic steroid unrelated to estrogens).
Role of estrogen receptors in
[Ca2+]i
response to estrogens.
To determine whether estrogen receptors are necessary for mediation of
the effect of E2 on
[Ca2+]i,
coronary artery smooth muscle cells were exposed for 3 min to the
estrogen-receptor antagonist ICI-182780 (1 µM; generously provided by
Zeneca Pharmaceuticals, Cheshire, UK). Subsequently, the cells were
exposed to endothelin-1, and when steady-state [Ca2+]i
was reached, the cells were exposed to either
E2 or
E2 (10 nM).
Effect of E2 on
Ca2+ efflux.
To block Ca2+ influx, cells were
exposed to zero extracellular Ca2+
or nifedipine (100 nM). The cells were then exposed to thapsigargin (1 mM) to block SR Ca2+ reuptake
(23), which resulted in a gradual increase in
[Ca2+]i,
plateauing after ~2 min. The cells were then exposed to
E2 in the presence or absence
of endothelin-1. To determine whether estrogen receptors mediate the
effect of E2 on
Ca2+ efflux under these
conditions, cells were preexposed to ICI-182780 (1 µM) before
endothelin-1 exposure. To confirm that
Ca2+ efflux was actually involved,
experiments were repeated in the presence of lanthanum (1 mM), which
nonselectively blocks both Ca2+
influx and efflux (28).
Effect of E2 on SR
Ca2+ release and
reuptake.
The response to caffeine (5 mM) was evaluated in the presence or
absence of preexposure to E2 in
cells in which Ca2+ influx and SR
Ca2+ reuptake were blocked by
nifedipine (or zero extracellular
Ca2+) and thapsigargin,
respectively. Under these conditions, SR
Ca2+ release was estimated from
the peak
[Ca2+]i response.
. SR
Ca2+ reuptake was estimated from
the initial rate of decline in
[Ca2+]i.
Effect of E2 on
Ca2+ influx.
Cells were exposed to BAY K 8644 (100 nM, 1 and 10 µM) to induce
Ca2+ influx. Nifedipine (100 nM)
completely blocked the elevation of
[Ca2+]i
induced by 100 nM and 1 µM BAY K 8644, but it only partially blocked
the
[Ca2+]i
response to 10 µM BAY K 8644. Accordingly,
Ca2+ influx was induced by 1 µM
BAY K 8644 in the presence of
E2.
.
Statistical analysis. In determining the statistical design for various experiments, the influence of interanimal variability in the [Ca2+]i response to 100 nM endothelin-1 was evaluated for 15 coronary artery smooth muscle cells from each of 10 animals using a one-way ANOVA. Interanimal variability was found to be nonsignificant at P > 0.25. Based on this result, the contribution of interanimal variability was determined to be insignificant, and the pooling of results from coronary artery smooth muscle cells obtained from different animals was justified. However, for each of the experimental protocols assessing the impact of estrogen on the [Ca2+]i response to 100 nM endothelin-1, cells from at least five animals were studied, and cells from any one animal did not represent >30% of the total. In addition, individual coronary artery smooth muscle cells were exposed to only one experimental protocol. The numbers of cells used for each protocol are reported in the results, and statistical analysis (one-way ANOVA) was based on this number. Statistical significance was tested at an 0.05 level. Data are reported as means ± SE. Reductions in [Ca2+]i are reported as percent changes from the maximum [Ca2+]i response.
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RESULTS |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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Estrogen levels and estrogen-receptor status.
Serum estrogen ranged from 37 to 103 pM and averaged 56 ± 10 pM in
all 10 animals. Immunocytochemical staining confirmed the presence of
estrogen receptors in coronary artery smooth muscle cells (Fig.
1). Although the immunocytochemical
procedure could not distinguish between nuclear and cytosolic estrogen
receptors, the higher intensity of fluorescence staining in the center
of the cell suggested the presence of nuclear receptors. However, immunoreactivity for cytosolic estrogen receptors distributed throughout the cell was also clearly present.
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[Ca2+]i
response to endothelin-1.
Basal
[Ca2+]i
levels were not significantly different among cells and ranged from 120 to 160 nM (131 ± 3 nM; n = 426).
At each concentration of endothelin-1, the
[Ca2+]i
response of 16 cells was determined. Endothelin-1 at 1 and 10 nM caused
a slow and sustained increase in
[Ca2+]i.
In comparison, 100 nM and 1 µM endothelin-1 caused a more rapid
increase in
[Ca2+]i,
reaching an initial peak after 4-30 s but then decreasing slowly
over the next 2-3 min to ~70% of the peak value. The
[Ca2+]i
responses to varying endothelin-1 concentrations at 30 s and 2 min are reported in Table 1.
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Effect of estrogens on endothelin-1-induced elevation of
[Ca2+]i.
The effect of E2 on the
[Ca2+]i
response to endothelin-1 was concentration dependent with an
ED50 of ~10 nM (Fig.
2A). The effect of 10 nM E2 on the
endothelin-1 dose-response (1, 10, and 100 nM) was determined (Fig.
2B). Although the
[Ca2+]i
response varied with endothelin-1 concentration, the inhibitory effect
of E2 was proportionately
similar across all endothelin-1 concentrations. Because the relative
effect of 10 nM E2 was
comparable across endothelin-1 concentrations, fixed concentrations of
E2 (10 nM) and endothelin-1
(100 nM) were used in all subsequent protocols.
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reduced
the elevation of
[Ca2+]i
induced by 100 nM endothelin-1 to near basal levels within a 15- to
45-s period (Fig. 3;
n = 56). The endothelin-1-induced
elevation in [Ca2+]i
was also reduced by 10 nM E2
(Fig. 3; n = 53), but to a lesser extent compared with E2. In
contrast, the
[Ca2+]i
response to endothelin-1 was unaffected by triamcinolone acetonide (Fig. 3; n = 14) or ethanol
(n = 15).
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Role of estrogen receptors in
[Ca2+]i
response to estrogens.
In the presence of ICI-182780,
E2 had no effect on the
[Ca2+]i
response to endothelin-1 (Fig. 4;
n = 51). In contrast, ICI-182780 did
not abolish the effect of E2 on
the
[Ca2+]i
response to endothelin-1 (Fig. 4; n = 32).
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Effect of E2 on
Ca2+ efflux.
When Ca2+ influx was blocked by
nifedipine (n = 22) or zero
extracellular Ca2+
(n = 13; data not shown), inhibition
of SR Ca2+ reuptake by
thapsigargin caused a gradual increase in
[Ca2+]i
(Fig. 5). Subsequent exposure to
E2 reduced
[Ca2+]i
by 95.1 ± 3.4% (Fig. 5; P < 0.05 compared with vehicle control). Under conditions of
blocked Ca2+ influx (nifedipine:
n = 32; zero extracellular
Ca2+:
n = 21; data not shown) and SR
Ca2+ reuptake (thapsigargin),
endothelin-1 induced a large increase in
[Ca2+]i
(Fig. 6). Subsequent exposure to
E2 reduced
[Ca2+]i
(Fig. 6). This reduction in
[Ca2+]i
was blocked by ICI-182780 (n = 22) and lanthanum (n = 31) (Fig. 6).
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Effect of E2 on SR
Ca2+ release and
reuptake.
Preexposure to E2 had no effect
on the amplitude of the initial response to 100 nM and 1 µM
endothelin-1. When Ca2+ influx and
SR Ca2+ reuptake were blocked, the
peak
[Ca2+]i
response to caffeine was comparable in the presence
(n = 24) and absence
(n = 25) of
E2 (Fig.
7). These results suggest that E2 had no effect on SR
Ca2+ release.
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(Fig. 7). These results
suggest that E2 had no effect
on SR Ca2+ reuptake.
Effect of E2 on
Ca2+ influx.
Exposure to E2 significantly
reduced the Ca2+ influx induced by
1 µM BAY K 8644 (Fig. 8). When
BKCa channels were blocked by iberiotoxin, E2 still reduced
the
[Ca2+]i
response to endothelin-1 (Fig. 8). However, this reduction in
[Ca2+]i
was significantly less than that in the absence of iberiotoxin (57.5 ± 4.1 vs. 95.1 ± 3.1%, respectively).
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DISCUSSION |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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In addition to confirming the inhibitory effect of estrogens on
Ca2+ influx in coronary artery
smooth muscle cells, the results of the present study also demonstrated
that estrogens decrease
[Ca2+]i
by enhancing Ca2+ efflux via a
receptor-mediated mechanism. The conclusion that E2 enhances
Ca2+ efflux was supported by three
observations: 1) the reduction in
[Ca2+]i
by E2 was blocked by the
estrogen-receptor antagonist ICI-182780; 2) the
E2-induced reduction in
[Ca2+]i
was observed even when Ca2+ influx
and reuptake were blocked; and 3)
the E2-induced reduction in
[Ca2+]i
was absent when both Ca2+ influx
and efflux were blocked by nifedipine (and/or zero
extracellular Ca2+) and lanthanum.
The enhancement of Ca2+ efflux by
E2 represents a novel mechanism
by which estrogens regulate
[Ca2+]i
in response to agonist stimulation. As would be expected, the relative
enhancement of Ca2+ efflux was
independent of the level of endothelin-1 stimulation, as indicated by
the comparable reduction in
[Ca2+]i
at different endothelin-1 concentrations, relative to the peak response
at each concentration (e.g., ~50% decrease from the peak response
with 10 nM E2). Confirmation of
the effect of E2 on Ca2+ efflux was derived primarily
from the fact that the response was blocked by lanthanum. However,
lanthanum also blocks Ca2+ influx,
which has been previously demonstrated to be inhibited by
E2. Therefore, we designed
studies to block Ca2+ influx
independent of any inhibition on
Ca2+ efflux.
In experimental protocols designed to examine the underlying mechanisms
of E2 action, a 100 nM
endothelin-1 concentration was selected based on studies by other
investigators (24, 28), who found that the initial
[Ca2+]i
response at similar endothelin-1 concentrations represents SR
Ca2+ release and that the
subsequent response represents a balance between
Ca2+ influx and efflux. In this
regard, the initial peak
[Ca2+]i
response at 100 nM endothelin-1 observed in our study most likely
reflects SR Ca2+ release, whereas
the lower steady state reflects a balance between Ca2+ influx and efflux. In
contrast, endothelin-1 concentrations of 10 nM or less elicit only
slow, monotonic elevations in
[Ca2+]i
(also observed in the present study), which most likely reflect Ca2+ influx (24). Accordingly, the
selection of 100 nM allowed the examination of both SR
Ca2+ release and
Ca2+ flux across the cell
membrane. In contrast to these measurements, studies using
multicellular coronary artery smooth muscle strips as well as single
cells have reported a decline in
[Ca2+]i
to baseline after the initial peak
[Ca2+]i
response to endothelin-1. However, it must be noted that this decline
in multicellular preparations occurred over a considerably longer time
period (>10 min) and most likely reflects the ensemble of individual
cellular responses.
The serum estrogen levels of ~50 pM are consistent with previous
reports in swine of 20-200 pM (7, 26). However, because estrous
stage was not controlled in the present study, the 50 pM value most
likely reflects an average across different stages. Given the picomolar
serum estrogen levels, the 10 nM concentration of
E2 used to examine
[Ca2+]i
regulation is supraphysiological. It is difficult to directly extrapolate the reduction in
[Ca2+]i
observed with 10 nM E2 in
single coronary artery smooth muscle cells to the extent of reduction
in vascular tone in vivo because, if anything, the estrogen
concentration at the tissue is likely to be smaller. However, it must
be noted that we observed decreases of 20-30% in
[Ca2+]i
even at E2 concentrations
between 100 pM and 1 nM. These observations would suggest that
circulating estrogen levels do decrease
[Ca2+]i
to a somewhat smaller extent, which would be consistent with a role of
estrogen as a modulator of vascular tone. We opted for a concentration
of 10 nM E2 because it
approximates an IC50 and thus
provided a greater sensitivity for assessing the effects of various
inhibitors and activators and distinguishing between the effects of
Ca2+ efflux versus other
mechanisms of estrogen action. It is difficult to compare the results
of the present study, in which 10 nM
E2 was used, with those of
previous reports because a wide range of estrogen concentrations have
been used in these studies (4, 14, 16, 19, 21a, 29) that are often
greater than circulating estrogen levels and considerably higher than
that used in the present study. Regardless, it appears that the
mechanisms by which estrogen modulates vascular tone are similar, and
it is likely that Ca2+ efflux
plays a role in estrogen-induced reduction of
[Ca2+]i
even in vivo.
The specificity of the E2
effect on
[Ca2+]i
regulation is supported by the fact that the estrogen-receptor
antagonist ICI-182780 blocked the
[Ca2+]i
response to E2. In addition,
compared with E2, the
biologically inactive isomer E2
at a similar concentration was significantly less potent in reducing
agonist-induced elevation of
[Ca2+]i,
consistent with previous studies (25, 31). The lack of inhibition of
the
[Ca2+]i
response to E2 by ICI-182780
suggests a nonspecific non-receptor-mediated effect of
E2. However, the mechanisms
underlying the effects of E2
are not clear. Finally, triamcinolone acetonide, a steroid not related
to estrogens, did not reduce the endothelin-1-induced elevation of
[Ca2+]i
in coronary artery smooth muscle cells. This also suggests that the
nonspecific effect of E2 is
unlikely to be an experimental artifact.
The relatively rapid changes in
[Ca2+]i
observed in the present study, occurring over seconds rather than
minutes or hours, are clearly not compatible with the classic genomic
mechanism for the action of E2,
which involves translocation of receptors to the nucleus and protein
synthesis (1, 12). Therefore, the acute effects observed in the present
study are nongenomic in nature and are also consistent with previous
studies both in vivo (13, 17, 30) and in vitro (5, 8, 9, 19, 21a, 25)
(also see Ref. 2 for a review). The existence of cytosolic estrogen receptors and the recent interest in the role of plasma membrane estrogen receptors are also indicative of nongenomic effects. It is
possible that these plasma membrane receptors are also involved in
[Ca2+]i
regulation by estrogens and mediate some of the effects on [Ca2+]i
observed in the present study. However, with the use of light microscopy, it was not possible to localize the estrogen receptors to
the plasma membrane.
In addition to an enhancing effect on
Ca2+ efflux, the results of the
present study also confirmed previous observations that E2 inhibits
Ca2+ influx (14, 19, 22, 29, 31).
For example, E2 inhibited the
BAY K 8644-induced elevation of
[Ca2+]i.
These results of the present study extend previous reports by
establishing that Ca2+ influx, at
least through L-type Ca2+
channels, is blocked even by nanomolar concentrations of estrogen, considerably smaller than those used in previous studies. In porcine coronary artery smooth muscle from castrated males, estrogens were
shown to activate BKCa channels
through a cGMP-dependent mechanism, thus indirectly reducing
Ca2+ influx (29). In the present
study, the observation that iberiotoxin (a potent inhibitor of
BKCa channels) decreased the
extent to which E2 reduced the
endothelin-1-induced elevation of
[Ca2+]i
supports this mechanism.
Also in general agreement with previous studies (14, 31) is the
observation that E2 had no
effect on SR Ca2+ release. In the
present study, E2 did not
affect the
[Ca2+]i
response to caffeine, an agonist for ryanodine-receptor channels. Endothelin-1 is also known to activate inositol 1,4,5-trisphosphate (IP3) production and release
Ca2+ through
IP3-receptor channels (10, 27). In
the present study, preexposure to
E2 did not affect the initial
[Ca2+]i
response to endothelin-1, suggesting that SR
Ca2+ release through
IP3-receptor channels is also not
affected. Indeed, in permeabilized vascular smooth muscle, Kitazawa et
al. (14) found that the force response to exogenous
IP3 was unaffected by
E2. Therefore, it is unlikely
that SR Ca2+ release through
either IP3- or ryanodine-receptor
pathways is affected by E2.
However, these observations do not rule out the possibility that
estrogens inhibit SR Ca2+ release
via other agonists and/or signal transduction pathways. For
example, Han et al. (4) found that
E2 does inhibit SR Ca2+ release induced by
thromboxane A2. Further
experimentation is required to distinguish between these potentially
differential mechanisms of estrogen action on the SR. In the present
study, the lack of an E2 effect
of the rate of
[Ca2+]i
decline under conditions of blocked
Ca2+ influx and efflux suggests
that SR Ca2+ reuptake is also
unaffected by estrogens. Thus the predominant site of action for
estrogens appears to be the plasma membrane.
In summary, the results of the present study demonstrate that
E2 enhances
Ca2+ efflux, thereby providing a
novel mechanism by which estrogens decrease the
[Ca2+]i
response to endothelin-1 in coronary artery smooth muscle cells from
gonad-intact female pigs. This effect of
E2 requires estrogen receptors.
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ACKNOWLEDGEMENTS |
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We thank Thomas Keller and Kevin Rud for expert technical assistance.
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FOOTNOTES |
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This research was supported by National Heart, Lung, and Blood Institute Grant HL-51736, the Mayo Foundation, and the University of Minnesota Graduate School. Y. S. Prakash was supported by a fellowship from Abbott Laboratories.
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. §1734 solely to indicate this fact.
Address for reprint requests: G. C. Sieck, Anesthesia Research, Mayo Clinic, Rochester, MN 55905 (E-mail: sieck.gary{at}mayo.edu).
Received 4 June 1998; accepted in final form 16 November 1998.
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REFERENCES |
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Top
Abstract
Introduction
Methods
Results
Discussion
References
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