Vol. 273, Issue 5, H2141-H2145, November 1997
Pelvic nerve stimulation-induced pressor responses in corpus
cavernosum of anesthetized dogs
Kazuhide
Ayajiki,
Hideshi
Hayashida,
Tomio
Okamura, and
Noboru
Toda
Department of Pharmacology, Shiga University of Medical Science,
Seta, Ohtsu 520-21, Japan
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ABSTRACT |
To analyze the
mechanism of penile erection and pathogenesis of impotence, pressures
in the corpus cavernosum in anesthetized dogs were measured. Pelvic
nerve stimulation produced pressor responses in a frequency-dependent
manner. Intravenous injections of
NG-nitro-L-arginine,
a nitric oxide (NO) synthase inhibitor, dose dependently attenuated the
response, and the inhibition was reversed by intravenous injection of
L-arginine but not of
D-arginine. The response was
also inhibited by
NG-nitro-L-arginine
injected into the corpus cavernosum, the potency being ~10 times of
that applied intravenously. The intracavernous injection of
L-arginine restored the
response.
NG,NG-dimethylarginine,
an endogenous NO synthase inhibitor, dose dependently attenuated the
stimulation-induced response, which was restored by an intracavernous
injection of L-arginine. An
intravenous injection of hexamethonium abolished the pressor response
to nerve stimulation, whereas phentolamine and atropine did not
significantly alter the response. These findings suggest that an
increase in intracavernous pressure caused by pelvic nerve stimulation
in anesthetized dogs is mediated by NO liberated from postganglionic
neurons that originate in the ganglion located in the vicinity of
corpus cavernosum.
nitric oxide; NG-nitro-L-arginine; NG, NG-dimethylarginine; intracavernous pressure
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INTRODUCTION |
NITRIC OXIDE (NO) is hypothesized to be an inhibitory
neurotransmitter from findings obtained in isolated rabbit, dog, and human penile corpora cavernosa (6, 7, 10, 12). Histochemical studies
have demonstrated the presence of NO synthase-immunoreactive or NADPH
diaphorase-positive nerve fibers innervating the corpus cavernosum (1,
2, 6). Electrical stimulation of the pelvic nerve increases
intracavernous pressure and produces penile erection in anesthetized
rats, rabbits, cats, and dogs (4, 8, 9, 13, 16), and the responses are
inhibited by NO synthase inhibitors, suggesting a mediation of NO
liberated from pelvic nerves in cavernous smooth muscle relaxation.
However, mechanisms underlying the penile erection and its impairment
in vivo have not systematically been analyzed.
Recent studies have revealed that
NG, NG-dimethylarginine
[asymmetric dimethylarginine (ADMA)], an endogenous NO
synthase inhibitor (11, 14), accumulates in the plasma of patients with
chronic renal failure (15). Increased production or decreased
elimination of the endogenous inhibitors produced locally or in the
circulation may participate in the genesis of impotence.
Therefore, the present study was undertaken to determine the neural
connections of the pelvic nerve between the site of electrical stimulation close to the pelvic plexus and corpus cavernosum muscle and
to quantitatively evaluate the effects of
NG-nitro-L-arginine
(L-NNA), an NO synthase
inhibitor, applied intravenously or into the corpus cavernosum,
compared with those of ADMA applied locally.
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MATERIALS AND METHODS |
These studies were approved by the Animal Care and Use Committee at
Shiga University of Medical Science (Japan).
Twenty-four male mongrel dogs weighing 9-13 kg were premedicated
with an intramuscular injection of ketamine (15 mg/kg) and anesthetized
with pentobarbital sodium (20 mg/kg) given intravenously, and stable
anesthetic conditions were maintained by additional injections as
needed. The animals were intubated to breathe spontaneously. Arterial
systolic and diastolic pressures were monitored with a pressure
transducer (MPU0.5, Toyo Measuring Instruments,
Tokyo, Japan) and amplifier (AP641G, Nihon-Koden Kogyo,
Tokyo, Japan) via a catheter inserted into the right femoral artery.
The heart rate was monitored by a cardiotachometer (AT610G, Nihon-Koden Kogyo). The abdomen was opened through a midline abdominal incision. The left pelvic nerve distal to the pelvic plexus was carefully isolated and placed on a bipolar electrode (Iwashiya-Kishimoto Medical
Instrument, Kyoto, Japan) connected to an electronic stimulator (Nihon-Koden Kogyo). Two 21-gauge venous needles were placed in the
cavity of the left corpus cavernosum (~2.0 mm apart); one was
connected to the pressure transducer and recorder, and the other was
used for the intracavernous drug injection. Drugs were applied
systemically via the right femoral vein or locally into the left corpus
cavernosum. The pelvic nerve was stimulated by 1.0-ms electrical square
pulses of 10 V at frequencies of 5, 10, and 20 Hz for a period of 10 s
at intervals of 7-15 min. After the stabilization of pressor
responses to the nerve stimulation at 5, 10, and 20 Hz, phentolamine (1 mg/kg iv), atropine (1 mg/kg iv), hexamethonium (4 mg/kg iv plus a
continuous intravenous infusion of 0.1 mg · kg
1 · min1),
or L-NNA (0.5, 1.0, and 2.0 mg/kg iv) was applied intravenously to 14 of 24 dogs. The effects of
phentolamine and hexamethonium were confirmed by an abolishment of
hypertensive action of intravenously injected norepinephrine (3 µg/kg) and a reversal of the reflex decrease in heart rate by
norepinephrine to tachycardia, respectively. Twenty minutes after
intravenous treatment with L-NNA
(2.0 mg/kg), D-arginine (500 mg/kg iv), or L-arginine (500 mg/kg iv), nerve stimulation was commenced. In the remaining dogs, the
effects of intracavernously injected
L-NNA (0.05 mg/kg),
NG-nitro-D-arginine
(D-NNA; 0.05 mg/kg), and ADMA
(0.25 and 0.5 mg/kg) on the pressor response to pelvic nerve
stimulation were examined. In this series of experiments, recovery of
the response was determined by intracavernous injections of
D- and
L-arginine (5 mg/kg for each
0.05 mg/kg of L-NNA and 1.5 mg/kg for each 0.5 mg/kg of ADMA).
The results are expressed as means ± SE. Statistical analyses were
made with Student's paired and unpaired
t-tests and Tukey's method after
one-way analysis of variance. Drugs used were
L-NNA and
D-NNA (Peptide Institute, Minoh,
Japan); L-arginine,
D-arginine, and hexamethonium
bromide (Nacalai Tesque, Kyoto, Japan); phentolamine mesylate
(Novartis, Takarazuka, Japan); atropine sulfate (Tanabe, Osaka, Japan);
dl-norepinephrine hydrochloride
(Sankyo, Tokyo, Japan); and ADMA (Sigma Chemical, St. Louis,
MO).
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RESULTS |
Intracavernous pressure under resting conditions in 24 anesthetized
dogs averaged 5.4 ± 1.2 cmH2O.
Pelvic nerve stimulation at frequencies of 5, 10, and 20 Hz increased
the pressure, with a visible penile erection in a frequency-dependent
manner. The stimulation-induced pressor response was not affected by
intravenous treatment with phentolamine (1 mg/kg;
n = 3 dogs) or atropine (1 mg/kg;
n = 6 dogs; Fig.
1, A and
B, respectively), whereas hexamethonium (4 mg/kg; n = 6 dogs)
abolished the response (Fig. 1C).
The pressor response was inhibited by intravenous injections of
L-NNA (0.5, 1, and 2 mg/kg) in a
dose-dependent manner (Fig. 2A).
Injections of L-arginine (500 mg/kg iv) restored the neurogenic response, whereas
D-arginine was without effect
(Fig. 2B). Mean values of the
duration of responses at the half-maximal pressure rise due to the
nerve stimulations at frequencies of 5, 10, and 20 Hz were 23.1 ± 2.2, 32.0 ± 3.2, and 59.5 ± 9.4 s, respectively. Inhibitions by
L-NNA in the magnitude and
duration of pressor responses were inversely dependent on the
stimulation frequencies. Typical recordings of the response before and
after the NO synthase inhibition are illustrated in Fig.
3. Changes by the inhibitor of systolic and
diastolic blood pressures and heart rate are summarized in Table
1. The increased diastolic blood pressures
caused by L-NNA (2 mg/kg) were
restored by the additional intravenous injection of
L-arginine (500 mg/kg; from 95.7 ± 3.6 to 88.9 ± 3.9 mmHg diastolic blood pressure;
P < 0.01 by paired
t-test;
n = 7 dogs).
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Fig. 1.
Modification of pressor response by intravenously applied phentolamine
(1 mg/kg; A), atropine (1 mg/kg;
B), and hexamethonium
(C6; 4 mg/kg; C) to
pelvic nerve stimulation (5, 10, and 20 Hz for 10 s) in corpus
cavernosum of anesthetized dogs. Freq., frequency. Values are means ± SE; n, no. of dogs.
Significantly different from control:
a P < 0.001;
b P < 0.01 (by unpaired t-test).
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Fig. 2.
Modification of pressor response by
NG-nitro-L-arginine
[L-NNA; 0.5, 1, and 2 mg/kg iv (L-NNA 0.5, L-NNA 1, and
L-NNA 2, respectively);
A] and by
L-NNA + L-arginine
(+L-Arg) or
D-arginine
(+D-Arg; 500 mg/kg iv;
B) to pelvic nerve stimulation (5, 10, and 20 Hz for 10 s) in corpus cavernosum of anesthetized dogs. In
A, dogs were first treated with
L-NNA (2 mg/kg), and then
D-Arg or
L-Arg was applied. Values are
means ± SE; n, no. of dogs.
Significantly different from control:
a P < 0.01;
b P < 0.05. Significantly different from
L-NNA + L-arginine,
c P < 0.05 (by Tukey's method).
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Fig. 3.
Typical tracings of pressor response to pelvic nerve stimulation (5, 10, and 20 Hz) in corpus cavernosum before (control;
top) and after treatment with
L-NNA (2 mg/kg iv;
middle) and with
L-NNA + L-Arg (500 mg/kg iv;
bottom).
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The pressor response to nerve stimulation was inhibited by
L-NNA (0.05 mg/kg; 71.6 ± 16.4% inhibition at 5 and 10 Hz; P < 0.05 by paired t-test;
n = 4 dogs) injected into the corpus
cavernosum but not by D-NNA
(0.05 mg/kg; Fig. 4). The intracavernous
injection of L-arginine (5 mg/kg) reversed the inhibition (Fig.
4A). ADMA (0.25 and 0.5 mg/kg by
intracavernous injection), an endogenous NO synthase inhibitor (14),
dose dependently attenuated the response to nerve stimulation (Fig.
5A). The
response was also restored by the addition of
L-arginine but not of
D-arginine (1.5 mg/kg by
intracavernous injection; Fig. 5B).
The drugs intracavernously applied did not affect the systemic blood
pressure, heart rate, or intracavernous pressure under resting
conditions.
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Fig. 4.
Modification of pressor response by
L-NNA [0.05 mg/kg
(L-NNA 0.05) by intracavernous
injection] and by L-NNA + L-Arg (5 mg/kg by intracavernous
injection; A) or by
D-NNA (0.05 mg/kg by
intracavernous injection; B) to
pelvic nerve stimulation (5, 10, and 20 Hz for 10 s) in corpus
cavernosum of anesthetized dogs. In A,
dogs were first treated with
L-NNA, and then
L-Arg was applied. Values are
means ± SE; n, no. of dogs.
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Fig. 5.
Modification of pressor response by
NG, NG-dimethylarginine
[ADMA; 0.25 and 0.5 mg/kg (ADMA 0.25 and ADMA 0.5, respectively)
by intracavernous injection; A]
and by ADMA (0.5 mg/kg) + L-Arg
or D-Arg (1.5 mg/kg by
intracavernous injection; B) to
pelvic nerve stimulation (5, 10, and 20 Hz for 10 s) in corpus
cavernosum of anesthetized dogs. In B,
dogs were first treated with ADMA, and then
D-Arg or
L-Arg was applied. Values are
means ± SE; n, no. of dogs.
Significantly different from control;
a P < 0.01;
b P < 0.05 (by Tukey's method).
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DISCUSSION |
Intravenous injection of L-NNA
dose dependently attenuated the pressor responses of the corpus
cavernosum in anesthetized dogs, the magnitude of inhibition being
inversely related to the stimulation frequency. The responses depressed
by L-NNA were restored by the
injection of L- but not of
D-arginine. Intracavernously applied L-NNA was also effective
in attenuating the pressor responses, the inhibitory potency being
~10 times that induced by intravenous injection. The attenuation was
restored by an additional injection of
L-arginine into the corpus
cavernosum. Similar results were also obtained in anesthetized dogs in
which the corpus cavernosum was treated with intracavernous
L-NNA methyl ester (13).
Transmural electrical stimulation relaxes strips of the canine corpus
cavernosum (6). The relaxation is abolished by
L-NNA and restored by
L-arginine; therefore, the
response is postulated to derive exclusively from NO liberated from
inhibitory nerves (6). Atropine failed to significantly reduce the
pressor response, suggesting that the release of NO from the
endothelium due to activation of muscarinic receptors from cholinergic
nerves by acetylcholine is not involved. These findings suggest that
the pressor response of the corpus cavernosum and the penile erection
by pelvic nerve stimulation are mediated by NO synthesized from
L-arginine in inhibitory nerve terminals. Involvement of neurogenic vasoactive intestinal peptide in
the pressor response to nerve stimulation was not excluded from the
study in vivo but has been ruled out in the earlier study with isolated
canine corpus cavernosum (6).
Intracavernously injected ADMA also inhibited the neurogenic pressor
response, and the inhibitory effect was reversed by
L-arginine, as was the case with
L-NNA. Endogenous NO synthase
inhibitors, when accumulated in the vicinity of cavernous tissues, are
expected to suppress the neurally induced penile erection. In patients with chronic renal failure, circulating concentrations of the endogenous inhibitor are raised to ~10 µM (15). The present study
revealed that the inhibition by 0.5 mg/kg of intravenous L-NNA of the neurogenic response
was comparable to that by 0.05 mg/kg of intracavernous
L-NNA, suggesting 10 times more
effectiveness with local application. If the intravenously applied drug
is supposed to be diluted to 1:100 (blood volume, approximately
of body weight), an effective dose of ADMA (0.25 mg/kg
intracavernously; Fig. 5) applied in the present study would lead to
the intracavernous concentration of 25 µg/ml (125 µM), which is one
order higher than the plasma concentration attained in renal failure
patients. It is intriguing to determine whether ADMA is produced
locally in the endothelium of the corpus cavernosum as in human
endothelial cells (3).
Pressor responses to pelvic nerve stimulation were not potentiated by
-adrenoceptor blockade with phentolamine. Isolated canine corpus
cavernosum strips responded to exogenously applied norepinephrine with
a contraction by activation of an -adrenoceptor, although the
magnitude is less than that of the response of penile arteries (5).
Therefore, electrical stimulation of the pelvic nerve under the
experimental conditions used may not release norepinephrine from
adrenergic nerves in the amount sufficient to interfere with the
pressor response to nitroxidergic nerve stimulation. Possible mediation
by muscarinic-receptor activation of the response would be ruled out
from the ineffectiveness of atropine in the neurogenic pressor response
(Fig. 1). On the other hand, hexamethonium abolished the response,
suggesting the neurons electrically stimulated to be preganglionic.
According to our preliminary histochemical studies with dog materials
(unpublished data) and those with human materials by
Burnett et al. (2), there are nerve cells and bundles containing NO
synthase immunoreactivity or NADPH diaphorase in the neighboring tissues of the corpus cavernosum. These findings suggest that electrical stimulation applied to pelvic nerves evokes action potentials in preganglionic fibers, and synaptic information via nicotinic receptors is transferred to postganglionic nitroxidergic neurons innervating the corpus cavernosum.
Elevation of the intracavernous pressure and penile erection in
anesthetized dogs would be mediated by NO liberated from inhibitory nerves. It appears that the nerve originates in the ganglion located in
the vicinity of the corpus cavernosum and that the pelvic plexus sends
nerve fibers to this ganglion. Although the possibility of local
accumulation of endogenous NO synthase inhibitors in the corpus
cavernosum is not ruled out, the raised concentration in the plasma of
renal failure patients so far reported could not be estimated to be
high enough to impair the neurogenic penile erection.
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FOOTNOTES |
Address reprint requests to N. Toda.
Received 19 May 1997; accepted in final form 9 July 1997.
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REFERENCES |
1.
Burnett, A. L.,
C. J. Lowenstein,
D. S. Bredt,
T. S. K. Chang,
and
S. H. Snyder.
Nitric oxide: a physiological mediator of penile election.
Science
257:
401-403,
1992[Abstract/Free Full Text].
2.
Burnett, A. L.,
S. L. Tillman,
T. S. Chang,
J. I. Epstein,
C. J. Lowenstein,
D. S. Bredt,
S. H. Snyder,
and
P. C. Walsh.
Immunohistochemical localization of nitric oxide synthase in the autonomic innervation of the human penis.
J. Urol.
150:
73-76,
1993[Medline].
3.
Fickling, S. A.,
A. M. Leone,
S. S. Nussey,
P. Vallance,
G. St,
and
J. Whitley.
Synthesis of NG,NG-dimethylarginine by human endothelial cells.
Endothelium
1:
137-140,
1993.
4.
Finberg, J. P. M.,
S. Levy,
and
Y. Vardi.
Inhibition of nerve stimulation-induced vasodilatation in corpora cavernosa of the pithed rat by blockade of nitric oxide synthase.
Br. J. Pharmacol.
108:
1038-1042,
1993[Medline].
5.
Hayashida, H.,
H. Fujimoto,
K. Yoshida,
T. Tomoyoshi,
T. Okamura,
and
N. Toda.
Comparison of neurogenic contraction and relaxation in canine corpus cavernosum and penile artery and vein.
Jpn. J. Pharmacol.
72:
231-240,
1996[Medline].
6.
Hayashida, H.,
T. Okamura,
T. Tomoyoshi,
and
N. Toda.
Neurogenic nitric oxide mediates relaxation of canine corpus cavernosum.
J. Urol.
155:
1122-1127,
1996[Medline].
7.
Holmquist, F.,
H. Hedlund,
and
K.-E. Andersson.
Characterization of inhibitory neurotransmission in the isolated corpus cavernosum from rabbit and man.
J. Physiol. (Lond.)
449:
295-311,
1992[Abstract/Free Full Text].
8.
Holmquist, F.,
C. G. Stief,
U. Jonas,
and
K.-E. Andersson.
Effects of the nitric oxide synthase inhibitor NG-nitro-L-arginine on the erectile response to cavernous nerve stimulation in the rabbit.
Acta Physiol. Scand.
143:
299-304,
1991[Medline].
9.
Keast, J. R.
A possible neural source of nitric oxide in the rat penis.
Neurosci. Lett.
143:
69-73,
1992[Medline].
10.
Kim, N.,
K. M. Azadzoi,
I. Goldstein,
and
I. Saenz de Tejada.
A nitric oxide-like factor mediates nonadrenergic noncholinergic neurogenic relaxation of penile corpus cavernosum smooth muscle.
J. Clin. Invest.
88:
112-118,
1991.
11.
Kotani, K.,
S. Ueno,
A. Sano,
and
Y. Kakimoto.
Isolation and identification of methylarginines from bovine brain.
J. Neurochem.
58:
1127-1129,
1992[Medline].
12.
Rajfer, J.,
W. J. Aronson,
P. A. Bush,
F. J. Dorey,
and
L. J. Ignarro.
Nitric oxide as a mediator of relaxation of the corpus cavernosum in response to nonadrenergic, noncholinergic neurotransmission.
N. Engl. J. Med.
326:
90-94,
1992[Abstract].
13.
Trigo-Rocha, F.,
W. J. Aronson,
M. Hohenfellner,
L. J. Ignarro,
J. Rajfer,
and
T. F. Lue.
Nitric oxide and cGMP: mediators of pelvic nerve-stimulated erection in dogs.
Am. J. Physiol.
264 (Heart Circ. Physiol. 33):
H419-H422,
1993[Abstract/Free Full Text].
14.
Vallance, P., A. Leone, A. Calver, J. Collier, and S. Moncada.
Endogenous dimethylarginine as an inhibitor of nitric oxide
synthesis. J. Cardiovasc. Pharmacol.
20, Suppl. 12: S60-S62, 1992.
15.
Vallance, P.,
A. Leone,
A. Calver,
J. Collier,
and
S. Moncada.
Accumulation of an endogenous inhibitor of nitric oxide synthesis in chronic renal failure.
Lancet
339:
572-575,
1992[Medline].
16.
Wang, R.,
F. R. Domer,
S. C. Sikka,
P. J. Kadowitz,
and
W. J. G. Hellstrom.
Nitric oxide mediates penile erection in cats.
J. Urol.
151:
234-237,
1994[Medline].
AJP Heart Circ Physiol 273(5):H2141-H2145
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