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The Journal of Neuroscience, September 15, 2002, 22(18):8063-8070
 -Adrenoceptor Agonists Stimulate Endothelial Nitric Oxide
Synthase in Rat Urinary Bladder Urothelial Cells
Lori A.
Birder1, 2,
Michele L.
Nealen4, 5,
Susanna
Kiss1,
William C.
de Groat2,
Michael J.
Caterina4, 5,
Edward
Wang1, 3,
Gerard
Apodaca1, 3, and
Anthony J.
Kanai1, 2
Laboratory of Epithelial Cell Biology, Renal-Electrolyte Division,
Departments of 1 Medicine, 2 Pharmacology, and
3 Cell Biology, University of Pittsburgh School of
Medicine, Pittsburgh, Pennsylvania 15213, and Departments of
4 Biological Chemistry and 5 Neuroscience,
Johns Hopkins University School of Medicine, Baltimore, Maryland 21205
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ABSTRACT |
We have investigated the intracellular signaling mechanisms
underlying the release of nitric oxide (NO) evoked by  -adrenoceptor (AR) agonists in urinary bladder strips and cultured bladder urothelial cells from adult rats. Reverse transcription-PCR revealed that inducible NO synthase and endothelial NOS but not neuronal NOS genes were expressed in urothelial cells. NO release from both urothelial cells and bladder strips was decreased (37-42%) in the
absence of extracellular Ca2+ (100 µM
EGTA) and was ablated after incubation with BAPTA-AM (5 µM) or caffeine (10 mM), indicating that the
NO production is mediated in part by intracellular calcium
stores. NO release was reduced (18-24%) by nifedipine (10 µM) and potentiated (29-32%) by incubation with the
Ca2+ channel opener BAYK8644 (1-10
µM). In addition, -AR-evoked NO release
(isoproterenol; dobutamine; terbutaline; 10 9 to
105 M) was blocked by the NOS
inhibitors NG-nitro-L-arginine
methyl ester (30 µM) or
NG-monomethyl-L-arginine
(50 µM), by -adrenoceptor antagonists (propranol,
1/2; atenolol, 1; ICI
118551; 2; 100 µM), or by the
calmodulin antagonist trifluoperazine (50 µM). Incubating cells with the nonhydrolyzable GTP analog GTP S (1 µM)
or the membrane-permeant cAMP analog dibutyryl-cAMP (10-100
µM) directly evoked NO release. Forskolin (10 µM) or the phosphodiesterase IBMX (50 µM)
enhanced (39-42%) agonist-evoked NO release. These results indicate
that -adrenoceptor stimulation activates the adenylate cyclase
pathway in bladder epithelial cells and initiates an increase in
intracellular Ca2+ that triggers NO production and
release. These findings are considered in light of recent reports that
urothelial cells may exhibit a number of "neuron-like" properties,
including the expression of receptors/ion channels similar to those
found in sensory neurons.
Key words:
nitric oxide; adrenergic; urothelium; urinary bladder; eNOS; iNOS
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INTRODUCTION |
There is increasing evidence that
nitric oxide (NO) produced by the enzyme NO synthase (NOS) is involved
in both physiologic and pathologic processes in the lower urinary tract
(LUT) (Andersson, 1993 ; Ehren et al., 1994; Folkerts and Nijkamp, 1998;
de Groat and Yoshimura, 2001). The putative physiological functions of NO in the LUT include the relaxation of urethral smooth muscle, modulation of transmitter release from efferent nerves, regulation of
urothelial permeability, and modulation of afferent nerve activity (Ehren et al., 1994; Andersson and Persson, 1995; Smet et al., 1996;
Ozawa et al., 1999; Lewis, 2000; Mumtaz et al., 2000; Yoshimura et al.,
2001). A pathological role of NO has also been suggested because injury
or chronic inflammation can upregulate the expression of inducible NOS
(iNOS) (Moncada et al., 1991; Kubes and McCafferty, 2000; Colansanti
and Suzuki, 2001). This raises the possibility that the transmitter
function of NO is plastic and can be altered by chronic pathological
conditions (Olsson et al., 1998; Kubes and McCafferty, 2000; Alfierei
et al., 2001; Morcos et al., 2001).
Stimulation of -adrenoceptors (ARs) in the urinary bladder (UB)
induces detrusor relaxation (Lefkowitz, 1996; Longhurst and Levendusky,
1999; Takeda et al., 2000; Igawa et al., 2001). Although this effect
clearly involves a direct action on smooth muscle, it may also be
mediated by release of "epithelium-derived relaxing factors" (which
include NO) from the urothelium (Hawthorn et al., 2000). Although there
are several possible sources of NO production, including endothelial
cells, nerves, smooth muscle, and urothelium, our studies demonstrated
that major sites of NO release were the urothelium and afferent nerves
(Birder et al., 1997, 1998, 2001). In the urinary bladder, NO can also
influence smooth muscle activity activated by reflex mechanisms.
Intravesical administration of NO donors suppresses detrusor
hyperactivity (Ozawa et al., 1999), whereas intravesical administration
of oxyhemoglobin, an NO scavenger, stimulates bladder activity (Pandita
et al., 2000). However, the effects of urothelial NO may not be
mediated by a direct action on smooth muscle, because bladder smooth
muscle cells (SMC) lack soluble guanylate cyclase, an important
component in NO-mediated relaxation (Smet et al., 1996; Fathian-Sabet
et al., 2001). Instead, NO may modulate bladder reflexes by altering
afferent nerve activity. Localization of afferent nerves next to the
urothelium suggests that chemicals released by these cells may
modulate afferent excitability. Thus, information about the mechanisms
of -adrenoceptor-evoked NO release from bladder urothelium may
provide insights into the role of urothelial cells (UCs) in bladder
sensory functions.
To better understand the mechanisms underlying -AR-induced
urothelial NO production, the present studies were designed to evaluate
the signaling pathway involved in NO release. In addition, to determine
the site of NO release, experiments evaluated -AR-evoked release
from innervated and denervated bladder strips and cultured urothelial
cells. Although cells in the urothelium of the rat urinary bladder have
been shown to exhibit NADPH-diaphorase (used as a marker for NOS)
(Persson et al., 1999), the identity of the NOS isoform present in the
urothelium has not been established. To explore this issue, we examined
the expression of the three NOS isoforms [neuronal NOS (nNOS),
iNOS, and endothelial NOS (eNOS)] in rat bladder strips, urothelial
cells, and bladder smooth muscle tissue (SMT) or cells.
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MATERIALS AND METHODS |
All procedures involving rats were conducted in accordance with
Institutional Animal Care and Use Committee policies.
Reverse transcription-PCR characterization. Tissue or
pelleted cultured cells were homogenized in TRIzol to isolate total RNA; poly(A+) RNA was further isolated
using Oligotex columns. Twenty nanograms of
poly(A+) RNA were reverse transcribed with
an oligo-dT primer in 50 mM Tris-Cl, 75 mM KCl, 3 mM
MgCl2, 0.01 M DTT, 20 U of
RNase inhibitor, and 0.5 mM dNTPs using 200 U of
Superscript II and then treated with 1 U of RNase H. PCR amplification
was performed in 20 mM Tris-Cl, 50 mM KCl, 1.5 mM
MgCl2, 0.2 mM dNTPs, and
0.4 µM primer pairs using 1.25 U of platinum
Taq. PCR cycling was initiated at 94°C for 2 min, followed
by: 94°C for 30 sec; annealing at 55°C for 30 sec (for iNOS) or
65°C for 30 sec (for eNOS and nNOS); 72°C for 1 min, and a final
extension step at 72°C for 2 min. Negative results were confirmed
using a 50 cycle reaction. Amplification primers were as follows:
iNOS, 5'-atggcttgcccttggaagtttctc-3' and
5'-cctctgatggtgccatcgggcatctg-3'; eNOS, 5'-ccttccggctgccacctgatcct-3' and 5'-aacatgtgtccttgctcgaggca-3' (Thuringer et al., 2000); nNOS, 5'-gaataccagcctgatccatggaa-3' and 5'-tccaggagggtgtccaccgcatg-3' (Shin
et al., 2000). Amplified products were visualized on a 1% agarose gel
using ethidium bromide. The presence or absence of a given product was
confirmed by transferring the agarose gels to nylon membranes,
prehybridization for 2 hr at 42°C, and overnight hybridization at
42°C with a 32P-labeled internal
oligonucleotide for each of the three isoforms. Probe sequences were as
follows: iNOS, 5'-ggacaagctgcatgtgactc-'3'; eNOS,
5'-caactggaccatctctaccg-3'; and nNOS, 5'-ggctgtgctttaatggagat-3'. Probes exhibited no cross-reactivity between isoforms. Further confirmation of the NOS isoform amplification was achieved by gel
extraction and sequencing of the PCR products.
Urothelial cell culture and cAMP accumulation. Preparation
and characterization of urothelial cultures have been described in
previous reports (Birder et al., 1998; Truschel et al., 1999; Birder et
al., 2001). Briefly, bladders were excised from deeply anesthetized
(urethane, 1.2 gm · kg1, i.p.)
Sprague Dawley rats (of either sex), cut open, and gently stretched
(urothelial side down). Anesthesia was determined to be adequate for
surgery by periodically testing for the absence of a withdrawal reflex
to a strong pinch of a hind paw and absence of an eye-blink reflex to
tactile stimulation of the cornea. After tissue removal, all animals
were killed via overdose of anesthetic. The tissue was incubated
overnight in minimal essential medium (Cellgro; Mediatech, Herndon,
VA), penicillin/streptomycin/fungizone, and 2.5 mg · ml1 dispase (Invitrogen,
Rockville, MD). The urothelium was gently scraped from underlying
tissue, treated with 0.25% trypsin, and resuspended in keratinocyte
medium (Invitrogen). The dissociated cell suspension (0.1 ml,
50,000-150,000 cells ml1) was plated on
the surface of collagen-coated dishes and maintained in culture for
1-3 d. Because long-term maintenance of cells in culture could
significantly change the properties of some types of cells (Bevan and
Winter, 1995), the cells in this study were examined after a short time
in culture. In general, all cells were used within the first 3 d
after plating. All cells in these cultures were cytokeratin positive
(Dako Corp., Carpinteria, CA) and therefore were presumably of
epithelial origin. For cAMP accumulation, urothelial cells were
aliquoted to contain 1 × 106
cells/ml and incubated with vehicle, isoproterenol (10 µM), or forskolin (10 µM). cAMP was quantified by radioimmunoassay
(cAMP Direct Biotrak System; Amersham Biosciences, Piscataway,
NJ) and expressed as picomoles of cAMP accumulated (increase
over basal levels) using a standard curve run in parallel.
Measurement of NO release. Urothelial cells and tissue
strips (bladder and urethra) obtained from deeply anesthetized rats were maintained in vitro in a temperature-regulated
oxygenated bath (37°C). They were perfused (1 ml · min1) with a solution
containing (in mmol/l): 4.8 KCl, 120 NaCl, 1.2 NaH2PO4, 1.1 MgSO4, 15.5 NaHCO3, 2 CaCl2, and 11 glucose, pH 7.4. The tip of an
NO-specific sensor (NO detection limit, 1 nM;
response time, 1 msec; tip diameter, 10-20 µm) was placed directly
onto the luminal surface of isolated urinary bladder or urethral strips or onto the surface of isolated urothelial cells (Kanai et al., 1995,
1997; Birder et al., 1998). The sensor was prepared by inserting carbon
strands (one to five fibers; Amoco, Greenville, SC) into glass
capillary tubes (1 mm internal diameter) pulled to a 100 µm opening
at one end. Copper wire was connected to the carbon fiber, with
electrically conductive epoxy at the blunt end, whereas the strand
protruded at the pulled end. The fiber was cut to the desired length
and coated with tetrakis
(3-methoxy-4-hydroxyphenyl)-nickel(II)porphyrin (TMHPPNi; Frontier
Scientific, Logan, UT). Monomeric TMHPPNi was dissolved in 0.1N NaOH
and deposited, as a polymeric film, on the carbon fiber using a
multiple-potential scanning cyclic voltammeter ( 0.2 to +1 V, model
283 Potentiostat/Galvanostat; PerkinElmer Instruments-Princeton
Applied Research, Oakridge, TN). Polymeric TMHPPNi catalyzes the
oxidation of NO to NO+. The cation
exchanger Nafion (Sigma, St. Louis, MO) was applied to the microsensors
by dipping in a 1% ethanol solution. The microsensors were
characterized by differential pulse voltammetry to determine the redox
potential of the oxidation of NO to NO+.
Chronoamperometry, performed at a constant potential 50 mV more positive than the redox potential, was used to determine the NO concentration. High-purity (>99.99%) NO standards were prepared daily
to accurately calibrate the electrodes. The currents generated by the
oxidation of NO to NO+ at the porphyrinic
interface were amplified and converted to voltages and then digitized
for analysis. Before drug application, controls were evaluated without
external stimuli and after the direct application of perfusate to
ensure that flow did not cause cellular disruption. In general, urinary
bladder strips were used within 2-4 hr after tissue removal, without
any appreciable decrease in ability to release NO. All compounds were
applied locally (at a distance 100 µm from cell) using a
microperfusion system (ALA Instruments, Westbury, NY) with 10 min
(agonists) or 20 min (antagonists) washout periods between applications
to prevent desensitization to repeated exposure. Agonists were applied
locally (1 sec pulse duration) under constant flow (1 ml · min1), and antagonists were
bath applied for 5 min. In view of the apparent lack of desensitization
between agonist applications, paired comparisons (either between
agonists or after varying concentrations of the same agonist) were made
using the same urinary bladder strips.
Denervation. In a separate group of deeply anesthetized
(halothane, 2%) animals, the major pelvic ganglia (MPG) were removed bilaterally (n = 5) to denervate the urinary bladder.
Five animals served as sham-operated controls in which the urinary
bladder was exposed via an abdominal incision. All animals survived an additional 4 d before tissue collection. Urinary bladder tissue strips were removed as described above and used to measure endogenous NO production.
Removal of the mucosa. To study the effect of agents on the
isolated urinary bladder mucosa containing the urothelial layer, the
mucosa was selectively removed from the urinary bladder smooth muscle
by pinning the isolated urinary bladder strips on a Sylgard-coated plate, then gently peeling the muscle layer away.
Materials. All reagents used for reverse transcription
(RT)-PCR were obtained from Invitrogen. Unless otherwise stated, all other chemical compounds were obtained from Sigma.
Data analysis. For all experiments, data (mean ± SEM)
represent measurements from a minimum of four to five strips or six to
seven cells per experimental treatment obtained from a minimum of three
to six animals. ANOVA and the Student-Newman-Keuls test were used for
multigroup comparisons. p values of <0.05 were considered statistically significant.
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RESULTS |
Type of NOS in urothelium, smooth muscle
RT-PCR revealed the expression of both iNOS and eNOS in
isolated urinary bladder UC (Fig. 1) as
well as urothelial tissue (UT). The latter contains urothelial cells,
along with connective, vascular, and nervous tissue. Although nNOS RNA
was identified in urothelial tissue, there was no evidence of nNOS
expression in cultured UC (Fig. 1). In contrast, all three NOS isoforms
(nNOS, iNOS, and eNOS) were expressed in cultured bladder SMC
(Fig. 1) and SMT (i.e., bladder strips in which the urothelium
was removed).
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Figure 1.
Identification of NOS isoforms in bladder tissue
and cultured cells. Ethidium bromide-stained agarose gels of RT-PCR
products (left column) and Southern blots (right
column) indicate the presence or absence of NOS isoforms in
cultured UC; UT containing urothelial cells, along with connective,
vascular, and nervous tissue; cultured SMC; and de-epithelialized
bladder strip (removal of epithelium from underlying smooth muscle)
SMT, containing smooth muscle cells and connective, vascular, and
nervous tissue. indicates no template control; + indicates rat brain
cDNA as a template. Expected product sizes: eNOS, 343 bp; iNOS, 827 bp;
nNOS, 701 bp. For nNOS, the positive and negative control lanes for the
Southern blot are from a shorter exposure to prevent masking of fainter
signals.
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Adrenoceptor agonist evoked NO release from isolated bladder and
urethral strips
Tissue strips were studied within 1-5 hr after isolation from the
urinary bladder or urethra. In the absence of chemical stimulation, basal NO release was not detectable (sensitivity, 1-5 nM
NO). In addition, application of perfusate did not elicit NO release. Isoproterenol (a nonselective -adrenoceptor, -AR agonist),
dobutamine (1-AR agonist), and terbutaline
(selective 2-AR agonist) at a concentration of
109 M did not elicit
detectable NO release; however, higher concentrations (108 to 105
M) evoked a transient concentration-dependent release of NO
from the luminal surface of urinary bladder strips (Table
1; Fig. 2A). For isoproterenol
and dobutamine, the magnitude of peak NO release was similar (490-650
nM NO), whereas the peak NO release after application of
terbutaline was significantly less (410-470 nM NO) (Table
1). The -AR agonists evoked a similar NO release (range, 400-650
nM NO) from urethral strips (data not shown). Paired
comparisons (either between agonists or after multiple applications of
the same agonist) were made using the same urinary bladder or urethral
strips (n = 4-5 strips). Successive application of
agonists (four to five applications with a 5 min washout period between
applications) elicited reproducible results (Fig.
2D). NO release began 100-200 msec after application
of agonist and continued for 2-6 sec.
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Table 1.
Magnitude of peak NO release (nM) induced by
increasing concentrations of the adrenoceptor agonists isoproterenol,
dobutamine, or terbutaline recorded in UB strips or UCs
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Figure 2.
Adrenoceptor agonists (isoproterenol,
dobutamine, terbutaline; 105 M) evoke
NO release from isolated bladder strips (A) or
isolated urothelial cells (B) from the rat
urinary bladder. Control, Basal NO release was
undetectable before drug application. A similar response was detected
from urethral strips. C, Peak NO response to
increasing concentrations (108 to
106 M) of isoproterenol in isolated
urothelial cells. Arrows indicate start of drug
application. D, Peak NO response to repeated application
of isoproterenol (ISO; 105
M) in isolated urothelial cells. Tracing is typical of that
seen in 10 separate recordings. Response was blocked by incubation with
the antagonist propranolol (104
M), and response to isoproterenol recovered after
washout. Each trace is typical of the data obtained from three to six
experiments (n = 3-6 animals) containing a total
of 40-60 cells.
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The responses to adrenoceptor agonists were ablated by application of
the NOS inhibitors
NG-nitro-L-arginine methyl
ester (L-NAME) (30 µM)
(Fig. 3A) or
NG-monomethyl-L-arginine
(L-NMMA) (50 µM;
data not shown). Adrenoceptor agonist-evoked NO release was also
blocked by application (106 to
104) of -AR antagonists (propranolol,
12,; atenolol,
1; ICI 118551, 2; data not shown). Although atenolol and ICI
118551 selectively blocked the response to dobutamine and terbutaline,
respectively, neither antagonist completely ablated the response to
isoproterenol. After a washout period (10 min), the response to
agonists fully recovered (Fig. 2D).
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Figure 3.
Effect of NOS antagonists on isoproterenol-evoked
NO release. The NO release evoked by isoproterenol (ISO;
105 M) in both normal urinary bladder
strips (A), and urothelial cells
(B) is reduced to a similar extent after
incubation with the NOS antagonists L-NAME (30 µM) or L-NMMA (50 µM; data not
shown). Dener indicates isoproterenol-evoked NO release
from denervated urinary bladder strips after bilateral removal of MPG
(4 d before). Similar effects were obtained with other adrenoceptor
agonists. Each bar is typical of the data obtained from
three to six experiments containing a total of 35-50 cells. Values
represent mean ± SEM; *significantly different from ISO alone.
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NO release after chronic denervation
To evaluate the contribution of nervous tissue to NO release, the
urinary bladder was denervated by bilateral removal of the MPG 4 d
before harvesting of the tissue. The urinary bladder appeared grossly
overdistended (mean urinary bladder weight, 272 ± 16 mg) compared
with bladders in sham-operated or neurally intact animals (mean urinary
bladder weight, 57 ± 7 mg). The lesioned animals' behavior was
unremarkable during their survival, with no visible signs of distress.
In isolated, denervated urinary bladder strips, basal release of NO was
not detected, and the NO release induced by application of adrenoceptor
agonists was not significantly different from release in tissues from
sham-operated (data not shown) or intact animals (Fig.
3A).
NO release in urothelial cells
To establish the urothelium as a possible source of NO, the
effects of -AR agonists were examined on cultured urinary bladder urothelial cells. Similar to results in bladder strips, basal NO
release was not detectable in the absence of stimuli. A transient concentration-dependent peak NO release was recorded in urothelial cells after application (108 to
105 M) of the -AR agonist
isoproterenol (79-547 nM NO), dobutamine (65-510
nM NO), and terbutaline (55-390 nM NO) (Table
1; Fig. 2B,C). The peak magnitude of the NO
concentration elicited by adrenoceptor stimulation was not
significantly different from that evoked in urinary bladder strips
(maximal response: 650 nM NO in strips; 610 nM NO in cells). When the influence of stimulus duration on NO release was evaluated, it was found that a brief (1 sec)
agonist pulse elicited a transient NO release (2-6 sec duration),
whereas a sustained (10 sec pulse) application of agonist elicited a
more prolonged (10-25 sec duration) NO release (Fig. 4A). Verification that
a measured NO response was from an individual urothelial cell was
demonstrated by raising the tip of the microsensor from the cell
surface and applying the agonist. As the distance from the cell surface
increased, there was a gradual decrease in the measured NO
concentration, and NO was undetectable beyond a distance of 30 µm
(Fig. 4B).
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Figure 4.
Influence of stimulus duration on peak NO release
from isolated urothelial cells. A, The left
trace depicts NO release after a brief 1 sec pulse
isoproterenol (ISO; 105
M) application; the right trace depicts NO
release after a sustained (10 sec duration) isoproterenol
(105 M) application. B,
NO release from an individual urothelial cell, as demonstrated by
raising the microsensor (from 15 to 30 µm) and reapplying
isoproterenol. Response was lost at a distance of 30 µm from the cell
surface. All NO recordings in this report were made from urothelial
cells with a  30 µm cell-free radius surrounding them.
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NO release from cultured cells by adrenoceptor agonists was blocked by
the NOS inhibitors L-NAME (30 µM) (Fig.
3B) or L-NMMA (50 µM; data not shown) as well as by the -AR
antagonists (105 to
104 M)
propranolol, atenolol, or ICI 118551 (data not shown). In addition,
release from urothelial cells was completely blocked by preincubation
(5 min) with the calmodulin antagonist trifluoperazine (50 µM; data not shown).
Involvement of calcium
Adrenoceptor-evoked NO release was dependent on both extracellular
and intracellular Ca2+. The dependence on
extracellular Ca2+ was demonstrated in
both bladder strips and isolated urothelial cells in three ways.
Agonist-evoked NO production was decreased (37 ± 5% in strips;
42 ± 7% in cells) after removal and chelation (100 µM EGTA) of extracellular
Ca2+, decreased (20-24 ± 5% in
strips; 18-21 ± 4% in cells) in the presence of the
dihydropyridine (DHP) Ca2+-channel
antagonist nifedipine (10 µM), and increased (29 ± 8% in strips; 32 ± 9% in cells) in the presence of the DHP
agonist BAYK8644 (1-10 µM) (Fig.
5A). Application of BAYK8644
alone did not evoke NO release, nor did an increase in the
[K+] in the medium to 50 mM (data not shown). In urothelial cultures, the
dependence on intracellular Ca2+ was
further demonstrated when agonist-evoked NO production was blocked
either after depletion of intracellular
Ca2+ stores with repeated applications of
caffeine (10 mM) or after ablation by incubation
with 5 µM BAPTA-AM in the absence of
extracellular calcium (100 µM EGTA) (Fig.
5A).
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Figure 5.
-adrenoceptor agonist activates the
adenylate cyclase pathway and initiates increased intracellular
Ca2+ and NO release in rat urothelial cells.
A, Inset, Transient NO release from
urothelial cells elicited by application of isoproterenol
(ISO; [Ca2+]o = 1.8 mM) was diminished in the absence
([Ca2+]o  0) of extracellular
calcium (100 µM EGTA). The graph depicts
isoproterenol-elicited NO production in urothelial cells (percentage
change in NO): [Ca2+]o 0;
isoproterenol-evoked NO release is diminished in the absence of
extracellular Ca2+. NIF, Reduction of
isoproterenol-evoked NO release after incubation with the L-type
Ca2+ channel antagonist nifedipine (10 µM); BAYK, increase in
isoproterenol-evoked NO release after incubation with BAYK8644 (10 µM); Caffeine, significant reduction in
isoproterenol-evoked NO release after repeated (n = 3) incubations with caffeine (10 mM);
BAPTA-AM, block of transient isoproterenol-evoked NO
release after incubation with BAPTA-AM (5 µM). A similar
response was detected in bladder strips (data not shown).
B, Transient NO release elicited by increasing
concentrations (10-100 µM) of the membrane-permeant cAMP
analog dibutyryl-cAMP. Arrows indicate the start of drug
application, which occurred 3 sec before the onset of NO release.
C, Isoproterenol-evoked NO release from isolated
urothelial cells is enhanced (percentage change in NO) after incubation
with either forskolin (10 µM) or the phosphodiesterase
inhibitor IBMX (50 µM). Data are based on calculations
from 30 to 50 cells per treatment, recorded in a minimum of three
independent experiments. Values represent mean ± SEM;
*significantly different from isoproterenol alone.
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Signaling pathways
In the presence of saponin (25 µg/ml), which increased membrane
permeability, loading of the cells with the nonhydrolyzable GDP analog
GDPS (10 µM) completely blocked the response to
agonist stimulation. However, after washout, the application of the
nonhydrolyzable GTP analog GTPS (1 µM) evoked direct
NO release (410-480 nM NO). In addition, NO was released
in a concentration-dependent manner (range, 50-290 nM NO)
by application of the membrane-permeant cAMP analog dibutyryl-cAMP
(10-100 µM) (Fig. 5B). Forskolin (10 µM), which directly activates adenylate
cyclase, increased cAMP levels 20-fold over untreated controls
(1.44 ± 0.5 pmol/ml to 20.5 ± 3.8 pmol/ml;
n = 3) and enhanced adrenergic-evoked NO production (39 ± 12% increase) (Fig. 5C). Adrenergic-evoked NO
production was also enhanced by the phosphodiesterase inhibitor IBMX
(50 µM; 42 ± 7% increase) (Fig.
5C). Neither forskolin nor IBMX exhibited any effect when
administered alone.
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DISCUSSION |
This study provided information about the site of action,
receptors, and signaling mechanisms underlying the release of NO in the
urinary bladder by -AR agonists. The analysis of NO release from
bladder strips prepared from innervated or denervated bladders and from
urothelial cells indicates that activation of
1 and 2
adrenoceptors in the urothelium is primarily responsible for the effect
of -AR agonists. The intracellular signaling pathway involves cAMP-
and Ca2+-dependent eNOS.
Because afferent and efferent nerves in the LUT express NOS and/or
NADPH diaphorase, a commonly used marker for NOS (Persson et al.,
1999), and because stimulation of afferent nerves with capsaicin
releases NO in the bladder (Birder et al., 1997, 2001), it was
important to determine the role of nervous tissue in the NO released by
-AR agonists. The contribution of nervous tissue to NO release was
evaluated using bladder strips from denervated bladders. -AR-evoked
NO release in denervated preparations did not differ significantly from
release in urinary bladder strips from sham-operated and neurally
intact controls, suggesting that the urothelium was a major source of
NO. This was confirmed by studying the effect of -AR stimuli on
cultured urothelial cells, which released NO in quantities similar to
those released by denervated or intact bladder strips.
Multiple subtypes of -ARs could mediate NO release, because
1, 2, and
3 receptors have been identified in the rat
bladder (Morrison et al., 1986). In the present studies, both
nonselective (isoproterenol) and selective (1,
dobutamine; 2, terbutaline) adrenoceptor
agonists released NO from the urothelium. The maximal responses to
isoproterenol and dobutamine were significantly larger than the
response to terbutaline, suggesting that 1
receptors might be more efficient than 2
receptors in triggering NO production. Alternatively, because
isoproterenol also activates 3-ARs (Trochu et
al., 1999), we cannot discount an involvement of
3-ARs in mediating NO release from the
urothelium. Additional studies using subtype-selective agents are
needed to explore this possibility.
Several lines of evidence suggest that -AR-evoked NO production is
mediated via a cAMP/adenylate cyclase (AC) pathway involving both extracellular and intracellular Ca2+.
Although the removal of extracellular Ca2+
suppressed the NO response, chelation of free intracellular calcium with BAPTA-AM abolished it. In addition, NO production was potentiated by the L-type calcium agonist BAYK8644 and partially inhibited by the
antagonist nifedipine. These results suggest that -AR-mediated NO
release is caused by both Ca2+ influx and
release from intracellular stores, consistent with observations in
vascular endothelium and airway epithelium (Kanai et al., 1995;
Tamaoki, 1995). Cell-permeant cAMP analogs were also sufficient to
release NO from urothelial cells, whereas forskolin and IBMX
potentiated the isoproterenol-evoked NO release. These data suggest
that cAMP production is responsible for the calcium-dependent activation of NOS in these cell types. Such a mechanism has also been
proposed in cardiac muscle, where -AR stimulation evokes NO
production in a Ca2+/calmodulin-dependent
manner, mediated through a cAMP/AC pathway (Kanai et al., 1997).
The basis of this apparent interaction between cAMP and
Ca2+ signaling pathways is unclear. It has
been shown that membrane-permeant cAMP analogs increase
Ca2+ channel activity in various cell
types (Kamp and Hell, 2000; Klein et al., 2000; Viard et al., 2000). In
addition, phosphorylation of cardiac and neuronal L-type channels by
cAMP-dependent protein kinases after -AR stimulation may play a role
in enhancing contractility or facilitating neurotransmitter release,
respectively (Sculptoreanu et al., 1993; Lefkowitz, 1996; Colansanti
and Suzuki, 2001). Moreover, the disinhibition of calcium channels in
the sarcoplasmic reticulum by cAMP-dependent protein kinase accounts
for cAMP-stimulated calcium release from intracellular stores in
cardiac myocytes (Kiriazis and Kranias, 2000). Analogous mechanisms may
be involved in -AR-mediated NO release in the urinary bladder urothelium.
A number of recent studies suggest that in nonexcitable cells, DHP
blocks store-operated channels that are depolarization insensitive
(Dutta, 2000). This could initially result in less Ca2+ reuptake into cellular stores,
leading to elevated cytoplasmic Ca2+
levels. However, eventually this would lead to more
Ca2+ being pumped out of the cell,
resulting in a net decrease in cellular
Ca2+ stores. Such store-operated channels
appear to be opened after Ca2+ release
into the cytoplasm via activation of IP3 or
ryanodine receptors. Our finding that nifedipine partially reduced
(18-24%) but did not completely block NO production is consistent
with studies in other types of nonexcitable cells and suggests that block of store-operated channels rather than block of voltage-gated L-type Ca2+ channels may be involved in
the observed DHP inhibition.
Our findings that NO release is blocked after removal of calcium and
chelation of intracellular stores and by a calmodulin antagonist,
trifluoperazine, are consistent with activation of a calcium-dependent
NOS. Of the three known NOS isoforms, we have identified the expression
of both the eNOS and iNOS forms in urinary bladder urothelial cells.
This is in contrast to urinary bladder smooth muscle cells, which
express all three NOS isoforms (eNOS, nNOS, and iNOS). These
observations are consistent with previous investigations, which
identified the eNOS isoform in the hamster urethral urothelium (Pinna
et al., 1999).
After damage to the urinary bladder, urothelium basal levels of NO can
be detected even in the absence of agonist. In this context, NO
generation is most likely caused by iNOS, which in other tissues is
upregulated by inflammatory stimuli and whose activity is independent
of calcium concentration (Moncada et al., 1991; Kubes and McCafferty,
2000; Colansanti and Suzuki, 2001). A role for iNOS in a normal,
uninflamed urinary bladder urothelium is less well established. Our
RT-PCR findings support the presence of iNOS in this tissue. However,
we did not detect agonist-independent release of NO from a normal
bladder urothelium. The reason for the discrepancy between iNOS mRNA
expression and the apparent absence of basal NO release from the normal
urothelium is unclear. It may reflect NO release below the sensitivity
of our microsensor, failure of urothelial cells to produce functional
iNOS protein from transcribed mRNA, and/or the presence of
factors that inhibit iNOS activity. Nevertheless, the expression of
iNOS mRNA in the normal urothelium suggests that NO production from
iNOS may be rapidly induced by pathological stimuli, such as bacterial
lipopolysaccharide (endotoxin). In this condition, NO release might be
elicited by activation of constitutively produced iNOS followed by the
upregulation of iNOS expression, which occurs after
injury/inflammation. Basal release of NO has been reported in normal,
uninflamed epithelium of the colon, where it has been speculated that
iNOS-induced NO may play a role in host defense mechanisms (Roberts et
al., 2001). In the placenta and fetal organs, iNOS is also normally
expressed, producing substantial amounts of NO without apparent toxic
consequences (Yoshiki et al., 2000). Thus, additional studies are
necessary to evaluate the role of iNOS in normal urinary bladder urothelium.
Nitric oxide is thought to be an important neurotransmitter in the
bladder neck and urethra (Andersson and Persson, 1995; Bennett et al.,
1995; Garcia-Pascual and Triguero, 2000). Thus, -AR-evoked NO
release in the urethra may function as an inhibitory neurotransmitter
to relax smooth muscle. Because the rat detrusor smooth muscle is
insensitive to NO, the detrusor smooth muscle is an unlikely target for
NO released from the bladder urothelium (Andersson and Persson, 1995;
Fujiwara et al., 2000; Fathian-Sabet et al., 2001). However, the
location of afferent nerves that terminate in close proximity to the
urothelium suggests that urothelium-derived NO may influence afferent
function. These nerves are poised to respond to neurotransmitters (NO,
ATP) released by urothelial cells, raising the possibility of a
chemical interaction between nerves and the urothelium (Namsivayam et
al., 1999; Birder et al., 2001; Vlaskovska et al., 2001).
However, increasing evidence suggests that NO may have a number of
complex effects that are dose dependent (Colansanti and Suzuki, 2001).
In terms of urinary bladder function, high concentrations of NO
produced by intravesical administration of NO donors depress bladder
hyperactivity after bladder irritation (Ozawa et al., 1999). In
addition, constitutively expressed NOS (nNOS and eNOS) is critical to
normal physiology (Moncada et al., 1991; Andersson and Persson, 1995;
Pandita et al., 2000). For example, NO production by constitutive NOS
may regulate epithelial permeability (Moncada et al., 1991; Kone and
Baylis, 1997; Lewis, 2000). Clinical studies have shown that NO levels
are decreased in some patients with interstitial cystitis, a clinical
syndrome characterized by chronic sensory symptoms, such as urinary
urgency, frequency, and pain (Korting et al., 1999). Thus, NO may be
both a beneficial and detrimental molecule, and alterations in NO
levels could affect urethral smooth muscle tone as well as the
excitability of sensory fibers within the urinary bladder (Yoshimura et
al., 2001).
In summary, the results of this study raise the possibility that
norepinephrine from adrenergic nerves in the bladder or catecholamines from the adrenal medulla could influence bladder function by acting on
-ARs in the urothelium to release NO and possibly other
neurotransmitters, such as ATP (Namsivayam et al., 1999; Vlaskovska et
al., 2001). Chemicals released from the urothelium could in turn affect
afferent nerves or smooth muscle or alter urothelial permeability
(Truschel et al., 1999; Cockayne et al., 2000; Hawthorn et al., 2000;
Lewis, 2000; Yoshimura et al., 2001). These data provide further
support for our previous speculation that the urothelium has
neuron-like properties and that it may play a role in sensory
mechanisms in the bladder (Birder et al., 2001).
| |
FOOTNOTES |
Received March 22, 2002; revised June 12, 2002; accepted June 20, 2002.
This work was supported by National Institutes of Health Grants DK54824
and DK57284 (L.A.B.), HL57985 (A.J.K.), and DK54425 (G.A.), and by
grants from the Blaustein Pain Research Fund and the American Cancer
Society (M.J.C.).
Correspondence should be addressed to Lori A. Birder, Laboratory
of Epithelial Cell Biology, Renal-Electrolyte Division, Department of
Medicine, University of Pittsburgh School of Medicine, A1220 Scaife
Hall, 3500 Terrace Street, Pittsburgh, PA 15213. E-mail: lbirder+{at}pitt.edu.
| |
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INTRODUCTION
