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Serotonin in the Rat Sympathetic Gangl on: Microdetermination of Monoamines and Their Metabolites by High-Performance Liquid Chromatographic Electrochemical Detection
Japan. J. Pharmacol, 35, 237-245
Serotonin
in the
Rat
of Monoamines Liquid
237
(1984)
Sympathetic
and
Their
Ganglion:
Metabolites
Chromatographic
Microdetermination by High-Performance
Electrochemical
Detection
Masami NIWA, Keiko KUNISADA, Akihiko HIMENO and Masayori OZAKI Departmentof Pharmacology2, NagasakiUniversitySchool of Medicine, 12-4 Sakamoto-machi,Nagasaki852, Japan Accepted March26, 1984
Abstract•\•\We
attempted
small
fluorescent
intensely
(SCG)
by
lation in
on
evaluating the
the
Wistar
1.19•}0.11
and
performance amount n=8)
SCG
of
of
The
increase
of
capsule
5-HT.
The
mode
decrease
of
was
the
thus of direct the
that
5- HT
connection serotonergic
in
slow 5-HIAA
electrical
the
5-HIAA in the
in
the
prewas
in
n=8,
not
rat and
to
the
case
our
injection
observed
to
content,
whereas
stimulation
SCG,
postganglionic
that
if so,
then
ganglion sympathetic
the
adult were high-
relatively large ng/capsule,
increased
the
(DOPAC)
the of
changes
DA
in
content and
DOPAC. content
increased
support
the
It for
be
would
existence
obtained.
neurons
the and
DOPAC
observed.
can
DA
content
5-HT
the
not
dopamine
(5-HIAA)
significantly were
and
in
without in
compared
sympathetic
of
changes
reverse-phase
acid
was
stimu-
assess
method. A SCG (0.62•}0.16
pargyline
content rat
was
acid by
the
ganglion
electrical
average•}S.E.)
induced-increase
was the
is produced
cell
The
content
Although
between
findings
electrochemical capsule of
pargyline
alter
cell
objective
determined
the
serotonergic
sympathetic
5-hydroxyindoleacetic
5-HT
content not
SIF
SIF
in
functional
and
3,4-dihydroxyphenylacetic
of
changes
serotonergic
with
5-HIAA.
the
reduced.
content,
appear a
5-HIAA did
markedly
DOPAC
and
a
cervical
The
(ng/ganglion,
the
rapidly.
Decentralization
fibers.
respectively,
decreased
of
superior
decentralization
compared
5-HT
detection
and
existence rat
pargyline,
contents
liquid chromatographic 5-HT was detected
of
in the
of
metabolism
0.11•}0.01,
without
content
effects
The rat
the
F) cell
sympathetic
(5-HT)
metabolism.
male
determine
(SI
preganglionic
serotonin
(DA)
to
A
through
demonstrated.
Mammalian sympathetic ganglia seem to possess various types of small intensely fluorescent (SIF) cells, among which the dopaminergic SIF cell is best understood (1, 2). The SIF cells in the sympathetic ganglia are composed of not only dopaminergic cells, but also other types of cells (3). The possible presence of a serotonergic SIF cell system in addition to the catecholaminergic cells in the rat SCG was suggested by the recent morphological studies of Verhofstad et al. (4). Taken in conjunction with earlier data that exogenous serotonin (5-HT) and its analogues stimulate ganglion cells and
modify neuronal transmission (5-7), the question arises as to whether the serotonergic SIF cell is functional in trans-synaptic neuronal transmission in the SCG. We compared the biochemical characteristics of 5-HT metabolism in the rat SCG with that of dopamine (DA) metabolism. The present study was designed 1) to confirm the existence of a 5-HT production system in the rat SCG and 2) to determine whether the activity of the ganglional 5-HT cell depends on preganglionic sympathetic neurons. In addition, our newly developed and sensitive quantitative analytical method of
238
M. Niwa et al.
catecholamines (CAs), 5-HT and their acidic metabolites, 3,4-di hydroxyphenylacetic acid (DOPAC), homovanillic acid (HVA) and 5hydroxyindoleacetic acid (5-H IAA), based on high-performance liquid chromatography (LC) with electrochemical detection (EC) is descri bed.
end
of
this
dissected
stimulation, out
plate
on
tissues
residual
pre-
off
the
the
an
(Data
and is
are
amines frozen of
few
hr
metabolites were
10%
(50
and for
were
assayed. in
an
CAs
ice-water
Branson,
KHz,
4
nate,
NaOH and
10
the
of
5-HIAA.
HCIO4
the
five of
added
15
min), ZnSO4-
injected
into
quantitation
of
the 5-HT
ZnSO4-HC104 into
quantitation
to and
the
of
of
homoge-
4•Ž,
injected
of id
vortexing
from
Fifty ƒÊl
an I FI ER
setting
was
rpm,
the
using
a
50 ƒÊl
After
was for
at
was for
homogenates
sec
Thirty
to
3%
CAs,
performed
(SON
supernatant
system
system
30
sec).
homogenates
LCEC and
30
(15,000
of
NaOH
for
added
id
acidic and
was
homogenate.
centrifugation 70 ƒÊl
IAA), HVA)
U.S.A.)
W,
was
residual
standards
homogenizer
185,
the
DOPPA
5-H
bath
probe
(20
(20
internal
Homogenization
5
N
the
(DOPAC,
Model
0.5
as
(5-HT, of
ultrasonic
3,4-
(DOPPA)
N-methyl-5-HT,
indoles
in
solution
3,4-dihydroxybenzylamine
used
respectively.
The 100 ƒÊl
ng/ml),
acid
were
metabolites
metabolites:
(10
ng/ml).
DHB
5-HT
preparations,
homogenized
dihydroxyphenylpropionic
(DHB)
capsule
EDTA-2Na
and
The
of
and
N-methyl-5-HT
ng/ml)
the
amounts
sample
ZnSO4-1.0%
containing
an
ice.
1).
after
and
SCG in
dry
because
amines
tissues
under
isolated
on
Table
of
carefully
washed
some
in
the were
plate
The
critical
given
a
was glass
frozen
contained
Determination Within
capsule
extensively
bath
SCG
and fibers
ice-cooled
were
decapsulation
connective
removed
(•~20).
capsule
the
glass
postganglionic
SCG, on
ice-water
of
were
cooled
the
been
a stereomicroscope and
ganglia a
After
had and
desheathed
Materials and Methods Animals, drug treatments and surgical procedures: Male Wistar rats weighing 250-300 g were fed a standard diet (F-2, Funabashi Farm Co., Chiba, Japan) and water ad libitum and housed at 24°C. These rats were given a 10% sucrose solution orally 24 hr before decapitation because the cereal chow contained tyrosine and DOPA which modify the level of the endogenous metabolites of biogenic amines (8). To confirm the existence of the 5-HT production system in the SCG, the experimental group and the control group were given pargyline, a monoamine oxidase inhibitor (75 mg/kg, i.p.) or the vehicle (0.9% NaCI) alone, respectively. Three groups of five experimental animals were decapitated at 5, 15 and 30 min after pargyline had been given i.p. Increases in the DA and 5-HT contents were measured within a few hr after the decapitation. To determine whether or not the activity of the ganglional 5-HT cell depends on the input from preganglionic neurons, two experiments were done. In the first, the SCG was decentralized by aseptic removal of several millimeters of the right sympathetic chain caudal to the ganglion. The decentralized and sham operated rats were decapitated 7 days after this surgery and ganglia were rapidly removed and placed on a cooled glass plate on ice. Ptosis in the right eye was taken as evidence of decentralization. In the second experiment, electrical monophasic stimulation (10 V, 10 Hz, 1 msec duration) to the right preganglionic nerves was performed after the bilateral SCG and preganglionic nerve were exposed, under conditions of urethane (1.2 g/kg, s.c.) anaesthetization. The stimulation was provided by a bipolar platinum electrode, a stimulator (3F-46, Sanei, Tokyo, Japan) and an isolator (5361, San-ei) for 3 and 10 min, respectively. At the
on
preparations:
fatty
cut
both
placed
ice.
Sample and
and
of
the
LCEC
DOPAC
and
HVA. Isolation natant
of was
alumina
(Wolem
activated
by
Sayre
(9).
pH 8.6 by HCI buffer conical
the
from
the
The
by
Neutral the
of was
of 0.5 transferred
vial The
alumina
by
superon
activity
supernatant
alumina.
residual absorption
method
the addition and then
reaction
activated into
CAs achieved
ml
containing CAs vortexing
Grade
I)
Anton
and
adjusted of to
to
3
M Trisa 0.5 ml
20 were
mg
of
absorbed for
5
min,
5-HT in Rat Sympathetic After
washing
were
eluted
with by
Eighty ƒÊl
of
into
LCEC
the
distilled
water,
100 ƒÊl
the
of
HCIO4
eluent
system
the
0.1
N was
for
CAs
HCI04. injected
quantitation
of
CAs. The
LCEC
6000A
system
pump,
Bondapak 0.39
C18 cm)
reverse
System,
the
the
case
of
5-HIAA
the
and
mobile
buffer,
pH
DOPAC in
were
HVA
and
case
of
pumped
at
temperature.
15.3 tration
20.6
internal
the
Drugs
and
the
0.6
others:
times DA
DA were
HVA
Chemical
carbon the
HCI,
creatinine
NA
bitartrate, from
U.S.A.
Co.)
using
the 3,4-
(DOPPA)
by
catalytic
temperature
and
10%
palladium
on
are
expressed
as
Values The
using
U.S.A.
HT
MO,
room
a catalyst.
differences
obtained WI,
purchased
Chemical
pressure
analyzed
was
acid
average±S.E.
of
run
3,4-dihydroxycinnamic
at
as
with were
5-
Co.,
from
atmospheric
9.0,
respective
Co.,
Dihydroxyphenylpropionic
(Aldrich
nor-
calculated
the
H Br
oxalate,
and
hydrogenation
of
compared
DHB
5-HIAA,
acid
room
concen-
was to
CAs
at
were
The
Chemical
DOPAC
prepared
octyl of
which
sulfate,
was
sodium
and
ratio
in
procedure.
5- HT
Sigma
In
5-HIAA,
ml/min
and
Aldrich
N -methyl-
the
methanol
respectively.
whole
of
5-HT,
mM
of
height
and
HVA.
quantitation
compounds
through
from
0.5 the
standard
authentic
case
9%
compound
peak
in
5-HT
and
retention
min,
+0.55
monochloroacetate
DHB
each
the
at
the
of
rate
The
of
from
a
(NA).
and
M
glassy
electrode
DOPAC
quantitation
the
adrenaline
in
an
working
of
containing
the
and
sulfate
V
0.15
3.5,
of
a
maintained
CAs,
phase,
case
with
quantitation
of
(30•~ and
The
reference
+0.70
quantitation
the
was
Ag/AgCI
a
Bioanaly-
equipped (TL-5).
potential
versus
column U.S.A.)
(LC-4A,
U.S.A.)
electrode
the
phase
electrode
of
injector, ƒÊ-
Assoc., detector
carbon
V
composed
universe
(Waters
electrochemical tical
was
U6K
statistical
between
mean
Student's
t-test.
significance values
was
Results Our 5-H of SCG
IAA
quantitation used
Lackovic was
method
in this et
al.
deproteinized
for
5-HT
study
is based
upon
(10).
First,
the
by
10%
and that
isolated ZnSO4
Ganglion
239
solutions and the homogenate alkalinized by the addition of NaOH. The advantage of this method is that a minute amount of 5-HIAA can be measured because 5-HIAA is more stable in alkaline than in acidic solution. The CAs, DOPAC and HVA are stable in acidic solution; therefore, we divided the ZnSO4 homogenate into two parts, and 0.5 N NaOH was added to one part for the quantitation of the 5-HT and 5-HIAA, and 3% HC104 was added to the other part for the quantitation of the CAs, DOPAC and HVA. Figure 1 and 2 show typical chromatograms obtained from rat SCGs (A) and capsule (B). The DOPAC (No. 1 peak in chromatograms), 5-HT (No. 2), N-methyl-5-HT (No. 3), DHB (No. 4), 5-HIAA (No. 5) and HVA (No. 6) were eluted from a reverse phase ii-Bondapak C18 column in the LCEC system with retention times of 15.0, 16.5, 21.5, 27.0 and 36.0 min, respectively. Under the conditions described in the section on Materials and Methods, a good separation of each compound was obtained. Chromatograms of Fig. 1 were obtained from ZnSO4-HCIO4 homogenates from rat SCGs (A) and capsule (B). The decrease of the peak height of DOPAC (No. 1) and HVA (No. 6) in a chromatogram (A2) obtained from the SCGs of a rat decapitated 15 min after pargyline (75 mg/kg, i.p.) treatment was observed when compared with that (Al) from SCGs of a control rat. The peaks of DOPAC and HVA were not observed in chromatogram (B) obtained from the capsule of the SCG. Although all peaks of the object compounds were present on the chromatogram (Al), calibration curves illustrated in the upper portion of the figure indicate the lack of linearity in 5-HT and 5-HIAA (the dotted lines), unlike the strict linearity of DOPAC and HVA. Standard curves for DOPAC and HVA were linear between 50 pg to 2 ng and 100 pg to 2 ng, respectively. A detection limit of 10-20 pg of DOPAC and 50 pg of HVA was obtained when it was defined as the amount giving a peak twice as high as the fluctuation from the baseline. As mentioned above, 5-HT and 5-HIAA could not be quantified under the conditions for measurement of DOPAC and HVA. Chromatograms for the quantitation of
240
M. Niwa et al.
5-HT and 5-HIAA obtained from ZnSO4NaOH homogenates of rat SCGs are shown in Fig. 2. The pargyline (75 mg/kg, i.p.) treatment increased the peak height of 5-HT
Fig.
1.
Typical
DOPAC combined gram (75
the
mg/kg,
i.p.,
in
15.0,
24.6
curves
of
line)
and upper
and
(P,
portion
of the
DOPAC of
observed,
and
HVA. (1)
chromatograms
treatment. observed
No in
HVA
the
peaks
No unlike
The and
of
chromatogram
times
5-HT
(•Z,
are
illustrated
linearities the
strict
decrease HVA
(6)
A2)
after
DOPAC of
of are the
capsule
were (B).
(B)
the
Peak
and
with
peak height
and
(•£) in of
times
and the
upper
of
was 5-HT
chromatogram
of
and of
of 5-HIAA
5-HT (5).
A2, (2)
The
of dotted
of
not
observed,
from in
21.5
portion
LCEC
and
27.0
5-HT line) figure.
As
illustrated
unlike
decreased
a
a
the
pargyline and
5-HT,
eluted
16.5,
5-HIAA.
The
conditions
column
(•Z,
4,
5-HIAA. the
a 2,
standard);
curves
DOPAC
DOPAC
linearity
height
of
Calibration
of
DOPAC;
5,
were C18
i.p.,
capsule
5-HIAA.
5-HIAA
retention
respectively.
the
under
5-HT
the
mg/kg,
1,
and
phase ƒÊ-Bondapak
min,
the
of
identities:
obtained of
of
(75
(internal
were
5-HT combined
chromatogram
standard);
quantitation
two
pargyline
chromatogram
SCG.
N-methyl-5-HT
strict
(A2)
with
(internal
linearity in
pargyline
and
illustrated
peak
HVA
for
rat,
ganglional of
N-methyl-5-HT
DOPPA
5-HIAA
5-HT
the
control treated
3,
of
Chromatogram
a rat
rat
system in
illustrated
a
min),
reverse
linearities
and the
of
dotted
of
of
control
chromatograms (Al)
chromatograms
Calibration
line)
figure.
(Al,
HVA
Typical
of
5-HT; of
C18
retention
(•£),
SCGs
were
respectively.
dotted
were
DOPAC
with
SCGs
5-
quantitation and
5-HIAA.
15
5,
DOPPA
2.
1,
(internal
phase ƒÊ-Bondapak
Fig. and of
identities:
the
DOPAC,
min,
(•œ),
pargyline
chromatograms
system
5-HIAA
two
chromatogram Peak
for
reverse
DOPAC
of
standard);
These
36.0
chromato-
N-methyl-5-HT
The a
LCEC
and
5- H IAA
heights the
a
(B)
SCG.
conditions
HVA. from
(A2) with
(internal
HVA.
ganglional
treated
and rat
3,
the
and
column
of
6,
rat,
rat
DOPPA
under
eluted
a
min),
5-HT;
and
DOPAC
control
of 15
4,
obtained
a
of Chromatogram
a control
2,
HIAA;
were
of
of
standard);
(Al)
SCGs
capsule
DOPAC;
the
HVA.
SCGs of
the
chromatograms
and
and decreased that of 5-HIAA, 15 min after injection (A2 in Fig. 2). The peak of HVA was not observed as HVA cannot be oxidized at
increased the
(•œ), are The the in the peak
5-HT in Rat Sympathetic
the potential of +0.55 V of a carbon electrode vs. Ag/AgCI reference electrode (11). As in Fig. 1, although we can observe the peak of DOPAC, the calibratory linearity of DOPAC was not observed, as indicated by the dotted line in the calibration curves cited in the upper portion of Fig. 2. Standard curves for 5-HT and 5-HIAA were linear between 50 pg to 2 ng. A detection limit of 20 pg of 5-HT and 5-H IAA was obtained. The CAs, DOPAC, HVA, 5-HT, 5-HIAA contents of SCG are summarized in Table 1. A minute amount of HVA was detected. The 5-HT was found both in the capsule of SCG and the SCG itself. As shown in Table 1, although the 5-HIAA, a main metabolite of 5-HT, was detected in the SCG, 5-HIAA was not measurable or was a smaller value than our minimum detection limit of 20 pg/sample
Ganglion
241
in the rat SCG capsule. Additionally, when we calculated the molecular ratio of DOPAC to DA and 5-HIAA to 5-HT, the former was 0.57•}0.05 (Each value is the average•}S.E. of 8 determinations.) and the latter was 0.10•}0.01. We found that the DOPAC/DA ratio was significantly higher than the 5HIAA/5-HT ratio (P<0.001, Student's ttest). The treatment with pargyline (75 mg/kg, i.p.), a monoamine oxidase inhibitor, in creased the content of DA and 5-HT with a decline of DOPAC, HVA and 5-H IAA. Figure 3A shows that the DA content rapidly increased, and the DOPAC content decreased exponentially. The increase of DA reached a plateau 5 min after pargyline treatment. The decline of HVA was slower than that of DOPAC. HVA was not detected 30 min after
Table 1. Biogenic amines (5-HT. DA and NA) and their acidic metabolites contents in rat SCG and capsule
Results
are the average•}S.E.
of 8 determinations.
(A)
Fig.
3.
Changes
pargyline. The figure. content **P<0
in
amines
Pargyline
contents
of
5-HT (A) .01
DA
(•œ) are and
and
was (•œ),
and indicated
***P<0.001,
(5-HIAA, DOPAC and HVA)
metabolites
injected DOPAC
i.p., (•œ,
5-HIAA after
(B)
(•œ,
dotted
dotted
treatment when
contents and
compared
the line)
line) with
(ng/ganglion) rats
in
were
and (B)
HVA of
pargyline. with
0 time.
in
decapitated
the
(•£,
dotted
figure.
Results
rat
SCG
at
the
time
line) In
are
the
the
(B),
are no
after
illustrated
changes
average•}S.E.
treatment
intervals in
(A)
of capsule of
with
indicated.
5 rats.
of
the
5-HT *P<0.05,
242
M. Niwa et al.
Table 2. Effect of decentralization on biogenic amines (5-HT and DA) and their acidic metabolites (5-HIAA, DOPAC and HVA) contents (ng/ganglion) in rat SCG
Decentralization was achieved by aseptic removal of theright sympathetic chain caudal to the ganglion (RS-decentralized SCG). The decentralized and sham operated rats were decapitated 7 days after surgery. RS: right side, LS: left side. Results are the average•}S.E. of 5 determinations. *P<0.05 when compared with the RS-sham operated SCG.
Table 3.
Effect of electrical stimulation on 5-HIAA, DOPAC and HVA contents (ng/ganglion)
in rat SCG
Electrical stimulation (10 V. 10 Hz, 1 msec duration) to the right preganglionic nerves was performed after the bilateral SCG and preganglionic nerves were exposed following anaesthetization with urethane (1.2 g/kg, s.c.) for 3 and 10 min. RS: right side, LS: left side. Results are the average•}S.E. of 5 determinations. *P<0.02, **P<0.001 when compared with the LS-nonstimulated (control) SCG.
the pargyline treatment. Although the increment of DA was rapid, the 5-HT content increased gradually (Fig. 3B). There were no significant differences between the values at 0, 5, and 15 min. Interestingly, the content of 5-HT in the capsule remained the same at all times after the pargyline treatment. Decentralization of the right side SCG induced a significant decrease of DOPAC content (RS-decentralized SCG) with a small increase in the left, sham-operated side (LSsham operated SCG). Unexpectedly, we observed no changes in the content of 5H IAA both in the decentralized side and the sham-operated side of the SCG (Table 2). This observation is noteworthy compared to the findings on the change of DOPAC content after decentralization. The effects of preganglionic stimulation on the contents of DOPAC, HVA and 5-H IAA are presented in Table 3. Whereas the content of DOPAC increased by 91% and 666%, respectively, at 3 and 10 min after stimulation (10 V.
10 Hz, 1 msec duration) we observed no increase in 5-H IAA content in the stimulatedright side of the SCG (RS-stimulated SCG.) Discussion We attempted to determine whether the serotonergic SI F cell is functional in ganglionic transmission between the preand postganglionic sympathetic neurons. Efforts were made to quantitate trace amounts of 5-HT and 5-HIAA. As described in Figs. 1 and 2, our modifications of the quantitative analysis of biogenic amines and their metabolites led to investigations of endogenous 5-HT systems in the rat SCG. This LCEC method is equally matched in sensitivity to the gas chromatographic-mass spectrometric method (12) and to the radioenzymatic microassay method (13). We measured the 5-HT and 5-HIAA contents in the rat SCG and its capsule separately because the capsule was presumed to have 5-HT storage cells, i.e., the mast cells, and it was technically
5-HT in Rat Sympathetic
difficult to avoid contamination from surfaceagglutinating blood which contains thrombocytic 5-HT, even when the capsulated SCG was extensively washed in an icewater bath. In fact, a relatively large amount of 5-HT existed in the capsule without detection of 5-HIAA. The low value of the ratio of 5-HIAA to 5-HT in the SCG is noteworthy. This is of particular interest in view of the finding that a high ratio of the central serotonergic neuron system was noted in a study concerning the regional brain contents of 5-HT and 5-H IAA (14). According to the data that the ratio is an index of changes in the activity of the monoaminergic system (15), this result suggests that the rat SCG has a low 5-HT neuronal activity. The effect of pargyline (75 mg/kg, i.p.) on the content of DA and DOPAC in this study is in complete accordance with findings in previous reports (16, 17). It has been thought that the turnover rate of DA in the dopaminergic SIF cell of the sympathetic ganglion is the same as the central dopaminergic neuron. The mode of the pargyline-induced 5-HT accumulation and 5-HIAA decrease may indicate low neuronal activity of the 5-HT system in the rat SCG compared with findings in the case of the central serotonergic neuron system (18). However, until more data are obtained with regard to the rate of formation of 5-HT and 5-HIAA calculated from the steady-state of kinetics, the low neuronal activity of the rat ganglionic 5-HT system remains only speculative. When we compared the decreased rate of the DOPAC content induced by pargyline, the ganglional 5-HT content increased gradually. This discrepancy may be explained by the suggestion that the nerve activity of the dopaminergic SIF cell is higher than that of the serotonergic SIF cell. The resulting high DOPAC/DA ratio and the low 5-HIAA/5-HT ratio support this idea, but one might question whether such a difference between dopaminergic and serotonergic metabolism reflects the deamination process of DA and 5-HT. Actually, 5-HT seems to be mainly deaminated by monoamine oxidase (MAO)-A, and the DA is deaminated by MAO-A and MAO-B in the rat brain (19). Moreover, pargyline is an
Ganglion
243
inhibitor of MAO-B (20). If such is indeed the case, then the different increases of DA and 5-HT may be based on neuronal activity, since a high dose (75 mg/kg) of pargyline can block both types of MAO (21). However, the present finding that pargyline did not increase 5-HT content in the SCG capsule, an area considered to contain mast cells and/or a small amount of blood, but did increase the 5-HT content of the SCG, supports the idea that 5-HT is produced by the neuronal structure in the rat SCG. We assumed that the 5-HT detected in the capsule was mainly derived from platelets of agglutinated blood, because platelets have only a small amount of tryptophan-hydroxylase (22), the ratelimiting enzyme of the biosynthesis of 5-HT, and take up the 5-HT from the blood and store it in the granules (23). As rat mast cells contain 5-HT (24), these cells are candidates for the origin of capsule 5-HT. The presence of specific receptors for 5-HT on ganglion cells in the SCG (25, 26), and the existence of a 5-HT cell indicated by immunohistochemical studies (4) led to the hypotheses that a serotonergic SIF cell may lie between the pre- and postganglionic sympathetic neurons. We did not detect any decrease of 5-H IAA content in the SCG after decentralization or any increase by preganglionic electrical stimulation (Tables 2 and 3). The serotonergic SIF cell does not seem to be stimulated by acetylcholine from the nerve endings of preganglionic sympathetic neurons. The serotonergic SIF cell may not influence the ganglionic neuronal transmission in the rat SCG. Similarly, unique and isolated serotonergic neurons were found in the rat pancreas (27) and in lamina X of the monkey spinal cord (28). Particularly, the latter spinal interneurons are considered to be one of the cerebrospinalcontacting neurons and to control spinal blood flow through vessel innervation (28). These studies suggest the physiological significance of the serotonergic SIF cell in the rat SCG. The possibility that the serotonergic SIF cell is innervated by the recurrent collateral from the postganglionic noradrenergic neuron cannot be entirely excluded since the ganglion cells have specific receptors for 5-HT (25, 26).
244
M. Niwa et al.
The changes in DOPAC presented in this study are in accord with data of other workers (17, 29). Electrical stimulation induced a dramatic increase in the DOPAC content, and the elevation was dependent on the time length of stimulation. Thus, measuring the DOPAC content in sympathetic ganglia may be a useful approach to assess the preganglionic sympathetic activity which is controlled by the descending bulbospinal monoaminergic neurons (30). Acknowledgement: We thank M. Ohara for adviceon the manuscriptand K.Katofor manuscript preparation.
10
11
12
References 1 Bjorklund, A., Cegrell, L., Falk, B., Ritzen, M. and Rosengren, E.: Dopamine-containing cells in sympathetic ganglia. Acta Physiol. Scand. 78, 334-338 (1970) 2 Libert, B.: Functional roles of SIF cells in slow synaptic action. In Histochemistry and Cell Biology of Autonomic Neurons, SIF Cells, and Paraneurons, Edited by Eranko, O., Soinila, S. and Paivarinta, H., p. 111-118, Raven Press, New York (1980) 3 Gerold, N., Enz, A., Schroder, H. and Heym, Ch.: Biochemical analysis of catecholamines in small intensely fluorescent (SIF) cells clusters of the rat superior cervical ganglion. J. Neurosci. Methods 6, 287-292 (1982) 4 Verhofstad, A.A.J., Steinbusch, H.W.M., Penke, B., Varga, J. and Joosten, H.W.J.: Serotoninimmunoreactive cells in the superior cervical ganglion of the rat. Evidence for the existence of separate serotoninand catecholaminecontaining small ganglion cells. Brain Res. 212, 39-49 (1981) 5 Hertzler E.C.: 5-Hydroxytryptamine and transmission in sympathetic ganglia. Br. J. Pharmacol. 17, 406-413 (1961) 6 Wallis, P.I. and Nash, H.L.: The action of methylated derivatives of 5-hydroxytryptamine at ganglionic receptors. Neuropharmacology 19, 465-472 (1980) 7 Wallis, D.I. and North, R.A.: The action of 5hydroxytryptamine on single neurons of the rabbit superior cervical ganglion. Neuropharmacology 17, 1023-1028 (1980) 8 Heffner, T.G., Hartman, J.A. and Seiden, L.S.: Feeding increases dopamine metabolism in the rat brain. Science 208, 1168-1170 (1980) 9 Anton, A.H. and Sayre, D.F.: A study of factors affecting the aluminium oxide-trihydroxyindole
13
14
15
16
17
18
19
procedure for the analysis of catecholamines. J. Pharmacol. Exp. Ther. 138, 360-375 (1962) Lackovic, Z., Parenti, M. and Neff, N.H.: Simultaneous determination of femtomole quantities of 5-hydroxytryptophan, serotonin and 5hydroxyindoleacetic acid in brain using H PLC with electrochemical detection. Eur. J. Pharmacol. 69, 347-352 (1981) Mefford, I.N.: Application of high performance liquid chromatography with electrochemical detection to neurochemical analysis: Measurement of catecholamines, serotonin and metabolism in rat brain. J. Neurosci. Methods 3, 207-224 (1981) Liuzzi, A., Foppen, F.H., Saavedra, J.M., LeviMontalcini, R. and Kopin, I.J.: Gas chromatographic-mass spectrometric assay of serotonin in rat superior cervical ganglia. Effects of nerve growth factor and 6-hydroxydopamine. Brain Res. 133, 354-357 (1977) Saavedra, J.M., Brownstein, M. and Axelrod, J.: A specific and sensitive enzymatic-isotopic microassay for serotonin in tissue. J. Pharmacol. Exp. Ther. 185, 508-515 (1973) Koch, D.D. and Kissinger, P.T.: I. Liquid chromatography with pre-column sample enrichment and electrochemical detection. Regional determination of serotonin and 5-hydroxyindoleacetic acid in brain tissue. Life Sci, 26, 1099-1107 (1980) Lavielle, S., Tassin, J.-P., Thierry, A.-M., Blanc, G., Nerve, D., Barthelemy, C. and Glowinski, J.: Blockade by benzodiazepines of the selective high increase in dopamine turnover induced by stress in mesocortical dopaminergic neurons of the rat. Brain Res. 168, 585-594 (1978) Karoum, F., Garrison, C.K., Neff, N. and Wyatt, R.J.: Trans-synaptic modulation of dopamine metabolism in the rat superior cervical ganglion. J. Pharmacol. Exp. Ther. 201, 654-661 (1977) Westerink, B.H.C. and Van Oene, J.C.: Evaluation of the effect of drugs on dopamine metabolism in the rat superior cervical ganglion by HPLC with electrochemical detection. Eur. J. Pharmacol. 65, 71-79 (1980) Johnson, M.D. and Crowley, W.R.: Serotonin turnover in individual brain nuclei: Evaluation of three methods using liquid chromatography with electrochemical detection. Life Sci. 31, 589-595 (1982) Garrick, N.A. and Murphy, D.L.: Differences in the preferential deamination of l-norepinephrine, dopamine and serotonin by MAO in rodent and primate brain. In Function and Regulation of Monoamines Enzymes: Basic and Clinical Aspects, Edited by Usdin, E., Weiner, N. and
5-HT in Rat Sympathetic
20
21
22
23
24
25
Youdim, M. B. H., p. 517-525, MacMillan Publishers, London (1981) Dewsbury, D.A., Davis, H.N., Jr. and Jansen, P.E.: Effects of monoamine oxidase inhibitors on the copulatory behaviour of male rats. Psychopharmacologia (Berlin) 24, 209-217 (1972) Knoll, J.: The pharmacology of selective MAO inhibitors. In Monoamine Oxidase Inhibitors: The State of the Art, Edited by Youdium, M.B.H. and Paykel, E.S., p. 45-61, John Wiley & Sons, Chichester (1981) Lovenberg, W., Jequier, E. and Sjoerdsma, A.: Tryptophan hydroxylation in mammalian system. Adv. Pharmacol. Chemother. 6A, 21-36 (1971) Tranzer, J.P., Da Prada, M. and Pletscher, A.: Electron microscopic study of the storage site of 5-hydroxytryptamine in blood platelets. Adv. Pharmacol. Chemother. 6A, 1 25-1 31 (1968) Benditt, E.P., Wong, R.L., Arase, M. and Roeper, E.: 5-Hydroxytryptamine in mast cells. Proc. Soc. Exp. Biol. Med. 90, 303-304 (1955) Haefely, W.: The effects of 5-hydroxytryptamine and some related compounds on the cat superior cervical ganglion in situ. Naunyn Schmiedebergs
Ganglion
245
Arch. Pharmacol. 281, 145-165 (1974) 26 Lansdown, M.J.R., Nash, H.L., Preston, P.R., Wallis, DI and Williams, R.G.: Antagonism of 5-hydroxytryptamine receptors by quipazine. Br. J. Pharmacol. 68, 525-532 (1980) 27 Koevary, S.B., Azmitia, E.C. and McEvoy, R.C.: Rat pancreatic serotonergic nerves: Morphologic, pharmacologic and physiologic studies. Brain Res. 265, 328-332 (1983) 28 lamotte, C.C., Johns, D.R. and de Lanerolle, N.C.: Immunohistochemical evidence of in doleamine neurons in monkey spinal cord. J. Comp. Neurol. 206, 359-370 (1982) 29 Pearson, J.D.M. and Sharman, D.F.: Increased concentrations of acidic metabolites of dopamine in the superior cervical ganglion following preganglionic stimulation in vivo. J. Neurochem. 22, 547-550 (1974) 30 Coote, J.H., Macleod, V.H., Fleetwood-Walker, S.M. and Gilby, M.P.: The response of individual sympathetic preganglionic neurons to microiontophoretically applied endogenous amines. Brain Res. 215,135-145 (1981)
Serotonin
in the
Rat
of Monoamines Liquid
237
(1984)
Sympathetic
and
Their
Ganglion:
Metabolites
Chromatographic
Microdetermination by High-Performance
Electrochemical
Detection
Masami NIWA, Keiko KUNISADA, Akihiko HIMENO and Masayori OZAKI Departmentof Pharmacology2, NagasakiUniversitySchool of Medicine, 12-4 Sakamoto-machi,Nagasaki852, Japan Accepted March26, 1984
Abstract•\•\We
attempted
small
fluorescent
intensely
(SCG)
by
lation in
on
evaluating the
the
Wistar
1.19•}0.11
and
performance amount n=8)
SCG
of
of
The
increase
of
capsule
5-HT.
The
mode
decrease
of
was
the
thus of direct the
that
5- HT
connection serotonergic
in
slow 5-HIAA
electrical
the
5-HIAA in the
in
the
prewas
in
n=8,
not
rat and
to
the
case
our
injection
observed
to
content,
whereas
stimulation
SCG,
postganglionic
that
if so,
then
ganglion sympathetic
the
adult were high-
relatively large ng/capsule,
increased
the
(DOPAC)
the of
changes
DA
in
content and
DOPAC. content
increased
support
the
It for
be
would
existence
obtained.
neurons
the and
DOPAC
observed.
can
DA
content
5-HT
the
not
dopamine
(5-HIAA)
significantly were
and
in
without in
compared
sympathetic
of
changes
reverse-phase
acid
was
stimu-
assess
method. A SCG (0.62•}0.16
pargyline
content rat
was
acid by
the
ganglion
electrical
average•}S.E.)
induced-increase
was the
is produced
cell
The
content
Although
between
findings
electrochemical capsule of
pargyline
alter
cell
objective
determined
the
serotonergic
sympathetic
5-hydroxyindoleacetic
5-HT
content not
SIF
SIF
in
functional
and
3,4-dihydroxyphenylacetic
of
changes
serotonergic
with
5-HIAA.
the
reduced.
content,
appear a
5-HIAA did
markedly
DOPAC
and
a
cervical
The
(ng/ganglion,
the
rapidly.
Decentralization
fibers.
respectively,
decreased
of
superior
decentralization
compared
5-HT
detection
and
existence rat
pargyline,
contents
liquid chromatographic 5-HT was detected
of
in the
of
metabolism
0.11•}0.01,
without
content
effects
The rat
the
F) cell
sympathetic
(5-HT)
metabolism.
male
determine
(SI
preganglionic
serotonin
(DA)
to
A
through
demonstrated.
Mammalian sympathetic ganglia seem to possess various types of small intensely fluorescent (SIF) cells, among which the dopaminergic SIF cell is best understood (1, 2). The SIF cells in the sympathetic ganglia are composed of not only dopaminergic cells, but also other types of cells (3). The possible presence of a serotonergic SIF cell system in addition to the catecholaminergic cells in the rat SCG was suggested by the recent morphological studies of Verhofstad et al. (4). Taken in conjunction with earlier data that exogenous serotonin (5-HT) and its analogues stimulate ganglion cells and
modify neuronal transmission (5-7), the question arises as to whether the serotonergic SIF cell is functional in trans-synaptic neuronal transmission in the SCG. We compared the biochemical characteristics of 5-HT metabolism in the rat SCG with that of dopamine (DA) metabolism. The present study was designed 1) to confirm the existence of a 5-HT production system in the rat SCG and 2) to determine whether the activity of the ganglional 5-HT cell depends on preganglionic sympathetic neurons. In addition, our newly developed and sensitive quantitative analytical method of
238
M. Niwa et al.
catecholamines (CAs), 5-HT and their acidic metabolites, 3,4-di hydroxyphenylacetic acid (DOPAC), homovanillic acid (HVA) and 5hydroxyindoleacetic acid (5-H IAA), based on high-performance liquid chromatography (LC) with electrochemical detection (EC) is descri bed.
end
of
this
dissected
stimulation, out
plate
on
tissues
residual
pre-
off
the
the
an
(Data
and is
are
amines frozen of
few
hr
metabolites were
10%
(50
and for
were
assayed. in
an
CAs
ice-water
Branson,
KHz,
4
nate,
NaOH and
10
the
of
5-HIAA.
HCIO4
the
five of
added
15
min), ZnSO4-
injected
into
quantitation
of
the 5-HT
ZnSO4-HC104 into
quantitation
to and
the
of
of
homoge-
4•Ž,
injected
of id
vortexing
from
Fifty ƒÊl
an I FI ER
setting
was
rpm,
the
using
a
50 ƒÊl
After
was for
at
was for
homogenates
sec
Thirty
to
3%
CAs,
performed
(SON
supernatant
system
system
30
sec).
homogenates
LCEC and
30
(15,000
of
NaOH
for
added
id
acidic and
was
homogenate.
centrifugation 70 ƒÊl
IAA), HVA)
U.S.A.)
W,
was
residual
standards
homogenizer
185,
the
DOPPA
5-H
bath
probe
(20
(20
internal
Homogenization
5
N
the
(DOPAC,
Model
0.5
as
(5-HT, of
ultrasonic
3,4-
(DOPPA)
N-methyl-5-HT,
indoles
in
solution
3,4-dihydroxybenzylamine
used
respectively.
The 100 ƒÊl
ng/ml),
acid
were
metabolites
metabolites:
(10
ng/ml).
DHB
5-HT
preparations,
homogenized
dihydroxyphenylpropionic
(DHB)
capsule
EDTA-2Na
and
The
of
and
N-methyl-5-HT
ng/ml)
the
amounts
sample
ZnSO4-1.0%
containing
an
ice.
1).
after
and
SCG in
dry
because
amines
tissues
under
isolated
on
Table
of
carefully
washed
some
in
the were
plate
The
critical
given
a
was glass
frozen
contained
Determination Within
capsule
extensively
bath
SCG
and fibers
ice-cooled
were
decapsulation
connective
removed
(•~20).
capsule
the
glass
postganglionic
SCG, on
ice-water
of
were
cooled
the
been
a stereomicroscope and
ganglia a
After
had and
desheathed
Materials and Methods Animals, drug treatments and surgical procedures: Male Wistar rats weighing 250-300 g were fed a standard diet (F-2, Funabashi Farm Co., Chiba, Japan) and water ad libitum and housed at 24°C. These rats were given a 10% sucrose solution orally 24 hr before decapitation because the cereal chow contained tyrosine and DOPA which modify the level of the endogenous metabolites of biogenic amines (8). To confirm the existence of the 5-HT production system in the SCG, the experimental group and the control group were given pargyline, a monoamine oxidase inhibitor (75 mg/kg, i.p.) or the vehicle (0.9% NaCI) alone, respectively. Three groups of five experimental animals were decapitated at 5, 15 and 30 min after pargyline had been given i.p. Increases in the DA and 5-HT contents were measured within a few hr after the decapitation. To determine whether or not the activity of the ganglional 5-HT cell depends on the input from preganglionic neurons, two experiments were done. In the first, the SCG was decentralized by aseptic removal of several millimeters of the right sympathetic chain caudal to the ganglion. The decentralized and sham operated rats were decapitated 7 days after this surgery and ganglia were rapidly removed and placed on a cooled glass plate on ice. Ptosis in the right eye was taken as evidence of decentralization. In the second experiment, electrical monophasic stimulation (10 V, 10 Hz, 1 msec duration) to the right preganglionic nerves was performed after the bilateral SCG and preganglionic nerve were exposed, under conditions of urethane (1.2 g/kg, s.c.) anaesthetization. The stimulation was provided by a bipolar platinum electrode, a stimulator (3F-46, Sanei, Tokyo, Japan) and an isolator (5361, San-ei) for 3 and 10 min, respectively. At the
on
preparations:
fatty
cut
both
placed
ice.
Sample and
and
of
the
LCEC
DOPAC
and
HVA. Isolation natant
of was
alumina
(Wolem
activated
by
Sayre
(9).
pH 8.6 by HCI buffer conical
the
from
the
The
by
Neutral the
of was
of 0.5 transferred
vial The
alumina
by
superon
activity
supernatant
alumina.
residual absorption
method
the addition and then
reaction
activated into
CAs achieved
ml
containing CAs vortexing
Grade
I)
Anton
and
adjusted of to
to
3
M Trisa 0.5 ml
20 were
mg
of
absorbed for
5
min,
5-HT in Rat Sympathetic After
washing
were
eluted
with by
Eighty ƒÊl
of
into
LCEC
the
distilled
water,
100 ƒÊl
the
of
HCIO4
eluent
system
the
0.1
N was
for
CAs
HCI04. injected
quantitation
of
CAs. The
LCEC
6000A
system
pump,
Bondapak 0.39
C18 cm)
reverse
System,
the
the
case
of
5-HIAA
the
and
mobile
buffer,
pH
DOPAC in
were
HVA
and
case
of
pumped
at
temperature.
15.3 tration
20.6
internal
the
Drugs
and
the
0.6
others:
times DA
DA were
HVA
Chemical
carbon the
HCI,
creatinine
NA
bitartrate, from
U.S.A.
Co.)
using
the 3,4-
(DOPPA)
by
catalytic
temperature
and
10%
palladium
on
are
expressed
as
Values The
using
U.S.A.
HT
MO,
room
a catalyst.
differences
obtained WI,
purchased
Chemical
pressure
analyzed
was
acid
average±S.E.
of
run
3,4-dihydroxycinnamic
at
as
with were
5-
Co.,
from
atmospheric
9.0,
respective
Co.,
Dihydroxyphenylpropionic
(Aldrich
nor-
calculated
the
H Br
oxalate,
and
hydrogenation
of
compared
DHB
5-HIAA,
acid
room
concen-
was to
CAs
at
were
The
Chemical
DOPAC
prepared
octyl of
which
sulfate,
was
sodium
and
ratio
in
procedure.
5- HT
Sigma
In
5-HIAA,
ml/min
and
Aldrich
N -methyl-
the
methanol
respectively.
whole
of
5-HT,
mM
of
height
and
HVA.
quantitation
compounds
through
from
0.5 the
standard
authentic
case
9%
compound
peak
in
5-HT
and
retention
min,
+0.55
monochloroacetate
DHB
each
the
at
the
of
rate
The
of
from
a
(NA).
and
M
glassy
electrode
DOPAC
quantitation
the
adrenaline
in
an
working
of
containing
the
and
sulfate
V
0.15
3.5,
of
a
maintained
CAs,
phase,
case
with
quantitation
of
(30•~ and
The
reference
+0.70
quantitation
the
was
Ag/AgCI
a
Bioanaly-
equipped (TL-5).
potential
versus
column U.S.A.)
(LC-4A,
U.S.A.)
electrode
the
phase
electrode
of
injector, ƒÊ-
Assoc., detector
carbon
V
composed
universe
(Waters
electrochemical tical
was
U6K
statistical
between
mean
Student's
t-test.
significance values
was
Results Our 5-H of SCG
IAA
quantitation used
Lackovic was
method
in this et
al.
deproteinized
for
5-HT
study
is based
upon
(10).
First,
the
by
10%
and that
isolated ZnSO4
Ganglion
239
solutions and the homogenate alkalinized by the addition of NaOH. The advantage of this method is that a minute amount of 5-HIAA can be measured because 5-HIAA is more stable in alkaline than in acidic solution. The CAs, DOPAC and HVA are stable in acidic solution; therefore, we divided the ZnSO4 homogenate into two parts, and 0.5 N NaOH was added to one part for the quantitation of the 5-HT and 5-HIAA, and 3% HC104 was added to the other part for the quantitation of the CAs, DOPAC and HVA. Figure 1 and 2 show typical chromatograms obtained from rat SCGs (A) and capsule (B). The DOPAC (No. 1 peak in chromatograms), 5-HT (No. 2), N-methyl-5-HT (No. 3), DHB (No. 4), 5-HIAA (No. 5) and HVA (No. 6) were eluted from a reverse phase ii-Bondapak C18 column in the LCEC system with retention times of 15.0, 16.5, 21.5, 27.0 and 36.0 min, respectively. Under the conditions described in the section on Materials and Methods, a good separation of each compound was obtained. Chromatograms of Fig. 1 were obtained from ZnSO4-HCIO4 homogenates from rat SCGs (A) and capsule (B). The decrease of the peak height of DOPAC (No. 1) and HVA (No. 6) in a chromatogram (A2) obtained from the SCGs of a rat decapitated 15 min after pargyline (75 mg/kg, i.p.) treatment was observed when compared with that (Al) from SCGs of a control rat. The peaks of DOPAC and HVA were not observed in chromatogram (B) obtained from the capsule of the SCG. Although all peaks of the object compounds were present on the chromatogram (Al), calibration curves illustrated in the upper portion of the figure indicate the lack of linearity in 5-HT and 5-HIAA (the dotted lines), unlike the strict linearity of DOPAC and HVA. Standard curves for DOPAC and HVA were linear between 50 pg to 2 ng and 100 pg to 2 ng, respectively. A detection limit of 10-20 pg of DOPAC and 50 pg of HVA was obtained when it was defined as the amount giving a peak twice as high as the fluctuation from the baseline. As mentioned above, 5-HT and 5-HIAA could not be quantified under the conditions for measurement of DOPAC and HVA. Chromatograms for the quantitation of
240
M. Niwa et al.
5-HT and 5-HIAA obtained from ZnSO4NaOH homogenates of rat SCGs are shown in Fig. 2. The pargyline (75 mg/kg, i.p.) treatment increased the peak height of 5-HT
Fig.
1.
Typical
DOPAC combined gram (75
the
mg/kg,
i.p.,
in
15.0,
24.6
curves
of
line)
and upper
and
(P,
portion
of the
DOPAC of
observed,
and
HVA. (1)
chromatograms
treatment. observed
No in
HVA
the
peaks
No unlike
The and
of
chromatogram
times
5-HT
(•Z,
are
illustrated
linearities the
strict
decrease HVA
(6)
A2)
after
DOPAC of
of are the
capsule
were (B).
(B)
the
Peak
and
with
peak height
and
(•£) in of
times
and the
upper
of
was 5-HT
chromatogram
of
and of
of 5-HIAA
5-HT (5).
A2, (2)
The
of dotted
of
not
observed,
from in
21.5
portion
LCEC
and
27.0
5-HT line) figure.
As
illustrated
unlike
decreased
a
a
the
pargyline and
5-HT,
eluted
16.5,
5-HIAA.
The
conditions
column
(•Z,
4,
5-HIAA. the
a 2,
standard);
curves
DOPAC
DOPAC
linearity
height
of
Calibration
of
DOPAC;
5,
were C18
i.p.,
capsule
5-HIAA.
5-HIAA
retention
respectively.
the
under
5-HT
the
mg/kg,
1,
and
phase ƒÊ-Bondapak
min,
the
of
identities:
obtained of
of
(75
(internal
were
5-HT combined
chromatogram
standard);
quantitation
two
pargyline
chromatogram
SCG.
N-methyl-5-HT
strict
(A2)
with
(internal
linearity in
pargyline
and
illustrated
peak
HVA
for
rat,
ganglional of
N-methyl-5-HT
DOPPA
5-HIAA
5-HT
the
control treated
3,
of
Chromatogram
a rat
rat
system in
illustrated
a
min),
reverse
linearities
and the
of
dotted
of
of
control
chromatograms (Al)
chromatograms
Calibration
line)
figure.
(Al,
HVA
Typical
of
5-HT; of
C18
retention
(•£),
SCGs
were
respectively.
dotted
were
DOPAC
with
SCGs
5-
quantitation and
5-HIAA.
15
5,
DOPPA
2.
1,
(internal
phase ƒÊ-Bondapak
Fig. and of
identities:
the
DOPAC,
min,
(•œ),
pargyline
chromatograms
system
5-HIAA
two
chromatogram Peak
for
reverse
DOPAC
of
standard);
These
36.0
chromato-
N-methyl-5-HT
The a
LCEC
and
5- H IAA
heights the
a
(B)
SCG.
conditions
HVA. from
(A2) with
(internal
HVA.
ganglional
treated
and rat
3,
the
and
column
of
6,
rat,
rat
DOPPA
under
eluted
a
min),
5-HT;
and
DOPAC
control
of 15
4,
obtained
a
of Chromatogram
a control
2,
HIAA;
were
of
of
standard);
(Al)
SCGs
capsule
DOPAC;
the
HVA.
SCGs of
the
chromatograms
and
and decreased that of 5-HIAA, 15 min after injection (A2 in Fig. 2). The peak of HVA was not observed as HVA cannot be oxidized at
increased the
(•œ), are The the in the peak
5-HT in Rat Sympathetic
the potential of +0.55 V of a carbon electrode vs. Ag/AgCI reference electrode (11). As in Fig. 1, although we can observe the peak of DOPAC, the calibratory linearity of DOPAC was not observed, as indicated by the dotted line in the calibration curves cited in the upper portion of Fig. 2. Standard curves for 5-HT and 5-HIAA were linear between 50 pg to 2 ng. A detection limit of 20 pg of 5-HT and 5-H IAA was obtained. The CAs, DOPAC, HVA, 5-HT, 5-HIAA contents of SCG are summarized in Table 1. A minute amount of HVA was detected. The 5-HT was found both in the capsule of SCG and the SCG itself. As shown in Table 1, although the 5-HIAA, a main metabolite of 5-HT, was detected in the SCG, 5-HIAA was not measurable or was a smaller value than our minimum detection limit of 20 pg/sample
Ganglion
241
in the rat SCG capsule. Additionally, when we calculated the molecular ratio of DOPAC to DA and 5-HIAA to 5-HT, the former was 0.57•}0.05 (Each value is the average•}S.E. of 8 determinations.) and the latter was 0.10•}0.01. We found that the DOPAC/DA ratio was significantly higher than the 5HIAA/5-HT ratio (P<0.001, Student's ttest). The treatment with pargyline (75 mg/kg, i.p.), a monoamine oxidase inhibitor, in creased the content of DA and 5-HT with a decline of DOPAC, HVA and 5-H IAA. Figure 3A shows that the DA content rapidly increased, and the DOPAC content decreased exponentially. The increase of DA reached a plateau 5 min after pargyline treatment. The decline of HVA was slower than that of DOPAC. HVA was not detected 30 min after
Table 1. Biogenic amines (5-HT. DA and NA) and their acidic metabolites contents in rat SCG and capsule
Results
are the average•}S.E.
of 8 determinations.
(A)
Fig.
3.
Changes
pargyline. The figure. content **P<0
in
amines
Pargyline
contents
of
5-HT (A) .01
DA
(•œ) are and
and
was (•œ),
and indicated
***P<0.001,
(5-HIAA, DOPAC and HVA)
metabolites
injected DOPAC
i.p., (•œ,
5-HIAA after
(B)
(•œ,
dotted
dotted
treatment when
contents and
compared
the line)
line) with
(ng/ganglion) rats
in
were
and (B)
HVA of
pargyline. with
0 time.
in
decapitated
the
(•£,
dotted
figure.
Results
rat
SCG
at
the
time
line) In
are
the
the
(B),
are no
after
illustrated
changes
average•}S.E.
treatment
intervals in
(A)
of capsule of
with
indicated.
5 rats.
of
the
5-HT *P<0.05,
242
M. Niwa et al.
Table 2. Effect of decentralization on biogenic amines (5-HT and DA) and their acidic metabolites (5-HIAA, DOPAC and HVA) contents (ng/ganglion) in rat SCG
Decentralization was achieved by aseptic removal of theright sympathetic chain caudal to the ganglion (RS-decentralized SCG). The decentralized and sham operated rats were decapitated 7 days after surgery. RS: right side, LS: left side. Results are the average•}S.E. of 5 determinations. *P<0.05 when compared with the RS-sham operated SCG.
Table 3.
Effect of electrical stimulation on 5-HIAA, DOPAC and HVA contents (ng/ganglion)
in rat SCG
Electrical stimulation (10 V. 10 Hz, 1 msec duration) to the right preganglionic nerves was performed after the bilateral SCG and preganglionic nerves were exposed following anaesthetization with urethane (1.2 g/kg, s.c.) for 3 and 10 min. RS: right side, LS: left side. Results are the average•}S.E. of 5 determinations. *P<0.02, **P<0.001 when compared with the LS-nonstimulated (control) SCG.
the pargyline treatment. Although the increment of DA was rapid, the 5-HT content increased gradually (Fig. 3B). There were no significant differences between the values at 0, 5, and 15 min. Interestingly, the content of 5-HT in the capsule remained the same at all times after the pargyline treatment. Decentralization of the right side SCG induced a significant decrease of DOPAC content (RS-decentralized SCG) with a small increase in the left, sham-operated side (LSsham operated SCG). Unexpectedly, we observed no changes in the content of 5H IAA both in the decentralized side and the sham-operated side of the SCG (Table 2). This observation is noteworthy compared to the findings on the change of DOPAC content after decentralization. The effects of preganglionic stimulation on the contents of DOPAC, HVA and 5-H IAA are presented in Table 3. Whereas the content of DOPAC increased by 91% and 666%, respectively, at 3 and 10 min after stimulation (10 V.
10 Hz, 1 msec duration) we observed no increase in 5-H IAA content in the stimulatedright side of the SCG (RS-stimulated SCG.) Discussion We attempted to determine whether the serotonergic SI F cell is functional in ganglionic transmission between the preand postganglionic sympathetic neurons. Efforts were made to quantitate trace amounts of 5-HT and 5-HIAA. As described in Figs. 1 and 2, our modifications of the quantitative analysis of biogenic amines and their metabolites led to investigations of endogenous 5-HT systems in the rat SCG. This LCEC method is equally matched in sensitivity to the gas chromatographic-mass spectrometric method (12) and to the radioenzymatic microassay method (13). We measured the 5-HT and 5-HIAA contents in the rat SCG and its capsule separately because the capsule was presumed to have 5-HT storage cells, i.e., the mast cells, and it was technically
5-HT in Rat Sympathetic
difficult to avoid contamination from surfaceagglutinating blood which contains thrombocytic 5-HT, even when the capsulated SCG was extensively washed in an icewater bath. In fact, a relatively large amount of 5-HT existed in the capsule without detection of 5-HIAA. The low value of the ratio of 5-HIAA to 5-HT in the SCG is noteworthy. This is of particular interest in view of the finding that a high ratio of the central serotonergic neuron system was noted in a study concerning the regional brain contents of 5-HT and 5-H IAA (14). According to the data that the ratio is an index of changes in the activity of the monoaminergic system (15), this result suggests that the rat SCG has a low 5-HT neuronal activity. The effect of pargyline (75 mg/kg, i.p.) on the content of DA and DOPAC in this study is in complete accordance with findings in previous reports (16, 17). It has been thought that the turnover rate of DA in the dopaminergic SIF cell of the sympathetic ganglion is the same as the central dopaminergic neuron. The mode of the pargyline-induced 5-HT accumulation and 5-HIAA decrease may indicate low neuronal activity of the 5-HT system in the rat SCG compared with findings in the case of the central serotonergic neuron system (18). However, until more data are obtained with regard to the rate of formation of 5-HT and 5-HIAA calculated from the steady-state of kinetics, the low neuronal activity of the rat ganglionic 5-HT system remains only speculative. When we compared the decreased rate of the DOPAC content induced by pargyline, the ganglional 5-HT content increased gradually. This discrepancy may be explained by the suggestion that the nerve activity of the dopaminergic SIF cell is higher than that of the serotonergic SIF cell. The resulting high DOPAC/DA ratio and the low 5-HIAA/5-HT ratio support this idea, but one might question whether such a difference between dopaminergic and serotonergic metabolism reflects the deamination process of DA and 5-HT. Actually, 5-HT seems to be mainly deaminated by monoamine oxidase (MAO)-A, and the DA is deaminated by MAO-A and MAO-B in the rat brain (19). Moreover, pargyline is an
Ganglion
243
inhibitor of MAO-B (20). If such is indeed the case, then the different increases of DA and 5-HT may be based on neuronal activity, since a high dose (75 mg/kg) of pargyline can block both types of MAO (21). However, the present finding that pargyline did not increase 5-HT content in the SCG capsule, an area considered to contain mast cells and/or a small amount of blood, but did increase the 5-HT content of the SCG, supports the idea that 5-HT is produced by the neuronal structure in the rat SCG. We assumed that the 5-HT detected in the capsule was mainly derived from platelets of agglutinated blood, because platelets have only a small amount of tryptophan-hydroxylase (22), the ratelimiting enzyme of the biosynthesis of 5-HT, and take up the 5-HT from the blood and store it in the granules (23). As rat mast cells contain 5-HT (24), these cells are candidates for the origin of capsule 5-HT. The presence of specific receptors for 5-HT on ganglion cells in the SCG (25, 26), and the existence of a 5-HT cell indicated by immunohistochemical studies (4) led to the hypotheses that a serotonergic SIF cell may lie between the pre- and postganglionic sympathetic neurons. We did not detect any decrease of 5-H IAA content in the SCG after decentralization or any increase by preganglionic electrical stimulation (Tables 2 and 3). The serotonergic SIF cell does not seem to be stimulated by acetylcholine from the nerve endings of preganglionic sympathetic neurons. The serotonergic SIF cell may not influence the ganglionic neuronal transmission in the rat SCG. Similarly, unique and isolated serotonergic neurons were found in the rat pancreas (27) and in lamina X of the monkey spinal cord (28). Particularly, the latter spinal interneurons are considered to be one of the cerebrospinalcontacting neurons and to control spinal blood flow through vessel innervation (28). These studies suggest the physiological significance of the serotonergic SIF cell in the rat SCG. The possibility that the serotonergic SIF cell is innervated by the recurrent collateral from the postganglionic noradrenergic neuron cannot be entirely excluded since the ganglion cells have specific receptors for 5-HT (25, 26).
244
M. Niwa et al.
The changes in DOPAC presented in this study are in accord with data of other workers (17, 29). Electrical stimulation induced a dramatic increase in the DOPAC content, and the elevation was dependent on the time length of stimulation. Thus, measuring the DOPAC content in sympathetic ganglia may be a useful approach to assess the preganglionic sympathetic activity which is controlled by the descending bulbospinal monoaminergic neurons (30). Acknowledgement: We thank M. Ohara for adviceon the manuscriptand K.Katofor manuscript preparation.
10
11
12
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5-HT in Rat Sympathetic
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Youdim, M. B. H., p. 517-525, MacMillan Publishers, London (1981) Dewsbury, D.A., Davis, H.N., Jr. and Jansen, P.E.: Effects of monoamine oxidase inhibitors on the copulatory behaviour of male rats. Psychopharmacologia (Berlin) 24, 209-217 (1972) Knoll, J.: The pharmacology of selective MAO inhibitors. In Monoamine Oxidase Inhibitors: The State of the Art, Edited by Youdium, M.B.H. and Paykel, E.S., p. 45-61, John Wiley & Sons, Chichester (1981) Lovenberg, W., Jequier, E. and Sjoerdsma, A.: Tryptophan hydroxylation in mammalian system. Adv. Pharmacol. Chemother. 6A, 21-36 (1971) Tranzer, J.P., Da Prada, M. and Pletscher, A.: Electron microscopic study of the storage site of 5-hydroxytryptamine in blood platelets. Adv. Pharmacol. Chemother. 6A, 1 25-1 31 (1968) Benditt, E.P., Wong, R.L., Arase, M. and Roeper, E.: 5-Hydroxytryptamine in mast cells. Proc. Soc. Exp. Biol. Med. 90, 303-304 (1955) Haefely, W.: The effects of 5-hydroxytryptamine and some related compounds on the cat superior cervical ganglion in situ. Naunyn Schmiedebergs
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