Vol. 274, Issue 3, R672-R676, March 1998
Opioid peptides mediate heat stress-induced immunosuppression
during pregnancy
Hiroyuki
Nakamura1,
Hirofumi
Nagase1,
Masami
Yoshida1,
Keiki
Ogino1,
Toshio
Seto2,
Kotaro
Hatta3, and
Ichiyo
Matsuzaki4
1 Department of Public Health,
Kanazawa University School of Medicine, Kanazawa
920; 2 Department of Public
Health, Kanazawa Medical University, Uchinada
920-02; 3 Department of
Psychiatry, Tokyo Metropolitan Bokuto Hospital, Tokyo 130; and
4 Institute of Community Medicine,
University of Tsukuba, Tsukuba, Ibaraki 305, Japan
 |
ABSTRACT |
To clarify the involvement of the opioid
system in enhanced immunosuppression induced by heat stress during
pregnancy, we examined the effects of heat exposure and
intraperitoneal administration of opioid receptor
antagonist naloxone on 
-endorphin (-EP) in blood, pituitary
lobes, and placenta as well as splenic natural killer cell activity
(NKCA) and placental steroids in pregnant rats at 15-16 days
gestation. Two-way analysis of variance revealed significant increases
in blood -EP induced by heat and naloxone and a significant
interaction between heat and naloxone on blood -EP and progesterone
(P). Whereas heat reduced NKCA, intraperitoneal administration of
naloxone reversed it. Significant increases in blood and placental
-EP induced by both heat and naloxone administration and a
significant interaction on blood and placental -EP was
observed. These results suggest that immunosuppression produced by heat stress during pregnancy is mediated by the opioid system. A positive correlation between -EP in blood and placenta during heat and naloxone administration suggests that increased placental -EP during heat results in hypersecretion of -EP into blood. P increased by heat during pregnancy may be involved in the
immunosuppression.
-endorphin; natural killer cell activity; pituitary; placenta; progesterone
| |
INTRODUCTION |
PREGNANCY PRODUCES adaptive modifications in the
homeostasis of the maternal immune system in the survival of the
fetoplacental graft (4, 12). Natural killer (NK) cells act early in the immune response before specificity can be generated. They mediate first-line defense by direct cytotoxicity against various types of
target cells without apparent prior immunization (34). Heat stress
during early or mild gestation pregnancy results in a high incidence of
embryo mortality (2, 33). Although we have previously demonstrated
enhanced immunosuppression produced by heat stress during pregnancy
(18), the neuroendocrine mechanisms in the immunosuppression for
pregnant mammals, including humans, exposed to heat stress remain to be
elucidated.
Since the immunoassay detection of opiate peptide -endorphin
(-EP) in placental extracts in 1978 (17), there has been considerable evidence showing the active presence of opiate receptors in human placental villous tissues (1, 35). Genomic and cDNA clones for
opioid receptors exist for several animal species, including mouse,
rat, guinea pig, and human (14). Human maternal plasma concentration of
-EP is elevated during pregnancy (20). Although the endogenous
opioid is involved in stress-induced immunosuppression (28), the effect
of pregnancy on immunosuppression during stress is unknown. Placental
steroids such as estrogens and progesterone (P) exert a positive effect
on the -EP content in the pituitary lobes (22). To examine the
involvement of the opioid system in enhanced immunosuppression induced
by heat stress during pregnancy, we examined the effects of heat
exposure and intraperitoneal administration of opioid receptor
antagonist naloxone on -EP in blood, pituitary lobes, and placenta
as well as splenic NK cell activity (NKCA) and placental steroids in
pregnant rats.
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MATERIALS AND METHODS |
Preparation of virgin and pregnant rats for
study. Twenty-four Wistar rats at 15-16 days
gestation, weighing 270 ± 4.69 g (means ± SE) were studied. For
breeding, a male rat was placed in a cage with two females. The
environment was controlled in all cases (23 ± 2°C, 50%
humidity), with alternating cycles of 12-h light (8 AM-8 PM) and
12-h dark. The onset of pregnancy was determined using vaginal smears.
All animals had access to commercial food and tap water ad libitum. The
rats were fasted, but given water in the 24 h before the experiment and
deprived of food and drink throughout the experiment. This study was
approved by the Ethics Committee on Animal Experimentation of Kanazawa
University, Takara-machi Campus. In all cases the experimental protocol
began at 11 AM. Twenty-four pregnant rats were divided into the
following four groups: six rats with intraperitoneal administration of
saline, but not exposed to heat; six rats with intraperitoneal
administration of saline before heat; six rats with intraperitoneal
administration of naloxone, but not exposed to heat; and six rats with
intraperitoneal administration of naloxone before heat.
Intraperitoneal administration of
naloxone. Naloxone HCl (Sigma, St Louis, MO) was
administered intraperitoneally at a dose of 0.2 ml of 10 mg/ml solution
in 0.9% saline 30 min before heat exposure. Twelve pregnant rats
received naloxone, and 12 received 0.2 ml of the saline alone. The
intraperitoneal administration dose of naloxone (2 mg/rat) is known to
reverse the effect of the opioid system on immune changes in rats (13,
24).
Exposure to heat stress. The use of a
microwave system is ideal for heat exposure because it allows for the
administration of an exact quantity of energy (9). The microwave
exposure device, described previously (11), was equipped with a
magnetron of 2,450 MHz as the source of energy and had an isolator to
vary the energy from the magnetron induced by reflection from the
applicator (350 × 470 × 455 mm). Twelve pregnant rats (6 rats subjected to saline and 6 rats to naloxone) were put into a
semicylindrical acrylic plastic holder (thickness, 5 mm; inside
diameter, 60 mm; length, 170 mm) and were exposed to microwaves at 10 mW/cm2 incident power density at
2,450 MHz for 90 min. The sham-exposed rats (6 rats subjected to saline
and 6 rats to naloxone) were treated in an identical manner, except
that the microwave generator was not turned on. During exposure, the
environment of the exposure facility was maintained at 21-23°C
and 50-60% humidity.
Measurements of blood corticosterone, -EP,
estradiol, and P. Blood samples were collected by
decapitation of rats immediately after the end of the protocol. Plasma
was immediately prepared by transfer of samples to cooled conical
centrifuge tubes containing 0.1 mM EDTA followed by centrifugation. The
plasma was frozen at 
80°C until analysis. Corticosterone
(CS) was measured by the fluorometric method of Silber et al. (30).
-EP was measured by the radioimmunoassay (RIA) described by Yoshimi
et al. (39). In this method, highly purified -EP was labeled with Na
125I using chloramine T. The purification of labeled -EP
was performed on a carboxymethyl cellulose column. The
antiserum against -EP showed negligible cross-reactivity with other
fragments of -lipotropin such as 
-melanocyte-stimulating
hormone and ACTH. Estradiol
(E2) and P were analyzed by RIA
using the tube solid-phase method of Ratcliffe et al. (25). The intra-
and interassay coefficients of variation were 8.0 and 12.5% for CS,
7.0 and 11.0% for -EP, 7.5 and 10.6% for
E2, and 5.4 and 7.6% for P,
respectively. The sensitivity of the assays for CS, -EP,
E2, and P were 5 ng/tube and 3, 2.5, and 1.1 pg/tube, respectively.
Splenic NKCA. To measure splenic NKCA,
the spleen was surgically excised and dissociated into a single-cell
suspension. The splenocytes were suspended in 40 ml phosphate-buffered
saline (PBS) and centrifuged in 50-ml tubes at 400 g at room temperature for 30 min over
12 ml Ficoll-Paque (Pharmacia, Piscataway, NJ) to yield mononuclear
cells (26). Splenic lymphocytes were collected at the interface, washed
twice in PBS solution, and suspended in RPMI 1640 medium (GIBCO, Grand
Island, NY) supplemented with 10% vol/vol fetal bovine serum (FBS;
GIBCO), 2 mM L-glutamine, 100 U/ml penicillin, and 100 ug/ml streptomycin, all from GIBCO.
NKCA was measured in a standard 4-h chromium (Cr) release assay that
was performed in 0.2-ml volumes in U-bottom microplates. The YAC-1
mouse lymphoma cell line was used as the target for detecting NK cell
cytotoxicity. The cells, suspended in culture in RPMI 1640 medium, were
labeled with
Na251CrO4
at 1 mCi/ml (New England Nuclear, Boston, MA) for 1 h at 37°C. The
cells were washed four times in a tissue culture medium consisting of
RPMI 1640 and resuspended in fresh medium, counted, and aliquotted at 1 × 104 target cells/well into
96-well U-bottom microtiter plates containing lymphocytes as effector
cells at predetermined concentrations. The effector-to-target cell
ratios (E/T) used were 40:1, 20:1, 10:1, and 5:1. After the plates were
incubated in 5% CO2 in air at
37°C for 4 h, the assays were terminated by centrifuging the plate
at 400 g for 5 min, after which the
medium was harvested from each well using a supernatant-harvesting
apparatus (Flow, McLean, VA). All determinations were done in
triplicate. Radioactivity was counted using a gamma counter.
Spontaneous 51Cr release,
determined by incubating labeled target cells in the medium alone, did
not exceed 10% of the maximum release that was determined by adding
1% Triton X-100. NKCA as percentage specific lysis was determined
according to the formula: 100 × [mean experimental counts/min (cpm) mean spontaneous cpm]/(mean maximal cpm mean spontaneous release cpm). Percent cytotoxicity was
calculated at each E/T, and these values were converted to lytic units
at 30% (LU30) according to the
method of Pross et al. (23). The intra- and interassay coefficients of
variance for LU30 as a measure of
NKCA were 7.5 and 18.2%, respectively.
Measurement of pituitary and placental
-EP. Immediately after the end of the
experiment, brains were removed and the anterior pituitary (AP) and
neurointermediate pituitary lobe (NIL) were dissected from the isolated
pituitary. The dissected regions were sonicated in 1 ml of 0.1 N acetic
acid, boiled for 10 min, and then centrifuged twice at 3,000 revolutions/min (rpm) at 4°C for 20 min.
For the excision of the maternal side of placenta, the placental disk
adjacent to the endometrium was separated with blunt forceps and mixed
with 10 ml PBS. The mixture was sonicated in 1 ml of 0.1 N acetic acid,
boiled for 10 min, and then centrifuged twice at 3,000 rpm at 4°C
for 20 min.
The supernatants of pituitary and brain extracts were stored at
80°C until analyses. Aliquots of the supernatants were
lyophilized and reconstituted in assay buffer for RIA for the
measurement of -EP. The pellets were dissolved in 1 N NaOH for
protein estimation. Protein concentration was determined as described
by Lowry et al. (15) using bovine serum albumin as a standard.
Statistical analysis. Statistical
analysis of the difference in the mean values of blood parameters,
splenic NKCA, and pituitary and placental -EP was performed by the
completely randomized design using two-way analysis of variance
(ANOVA). The factors were heat stress, which was composed of two levels
(control or heat), and intraperitoneal administration, which was also
composed of two levels (saline or naloxone). All statistical tests were two tailed. P values <0.05 were
regarded as statistically significant.
| |
RESULTS |
Blood CS, -EP, E2, and P in
heat-exposed or nonexposed pregnant rats with intraperitoneal
administration with saline or naloxone are shown in Table
1. Two-way ANOVA revealed that heat stress significantly increased CS and -EP and decreased
E2, independent of naloxone
administration. The ANOVA showed that naloxone administration significantly increased -EP. There were significant interactions between heat and naloxone administration on -EP and P. Effects of
heat stress and intraperitoneal administration of naloxone on splenic
NKCA in pregnant rats are demonstrated in Fig.
1. Whereas heat reduced NKCA,
intraperitoneal administration of naloxone reversed it. There was a
significant interactive effect on NKCA. We could observe significant
increases in placental -EP induced by both heat and naloxone
administration and a significant interaction on it.
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Table 1.
Effects of heat stress and intraperitoneal administration of naloxone
before stress on blood indicators in pregnant rats
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Fig. 1.
Effects of heat stress and intraperitoneal administration of naloxone
on splenic natural killer cell activity (NKCA) in pregnant rats. Values
represent means ± SE. Statistical analysis of difference was
performed by 2-way analysis of variance. Significant main effect of
heat [F(1,20) = 6.67, P < 0.05] and naloxone
[F(1,20) = 6.28, P < 0.05] and interactive
effect on NKCA [F(1,20) = 9.46, P < 0.01].
LU30, Lytic units at 30%.
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Heat was found to increase -EP in AP, NIL, and placenta
significantly. Intraperitoneal administration of naloxone significantly increased -EP in placenta. A significant interaction on -EP in
placenta was observed (Table 2).
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Table 2.
Effects of heat stress and intraperitoneal administration of naloxone
before stress on -EP concentration in the pituitary and
placenta of pregnant rats
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DISCUSSION |
Functional networks among nervous, endocrine, and immune systems are
now interpreted as a neuroimmunoendocrine function (29). Corticotropin-releasing hormone (CRH; 3, 36) and opiate -EP (16, 37)
play roles in modulating neuroendocrine and immune systems as
neurotransmitters. In agreement with a previous study (18), heat
reduced NKCA in pregnant rats. Furthermore, we observed a promoting
effect of naloxone administration as well as an interactive effect
between heat and naloxone on NKCA. These results suggest that naloxone
administration antagonizes immunosuppression induced by heat.
Therefore, immunosuppression after heat stress during pregnancy seems
to be mediated by the opioid system.
Gel filtration chromatography for -EP in placental and pituitary
extracts has shown that placental -EP is not involved in analgesia
induced by opioid-dependent stress, but plays a paracrine and autocrine
role during pregnancy (5). Although the elevation in -EP induced by
heat stress was seen in blood as well as pituitary and placenta, the
interactive effect between heat and naloxone on -EP was seen only in
blood and placenta. This result implies that naloxone administration
increases -EP in blood and placenta only in heat-exposed rats,
supporting the presence of opioid receptors in the placenta, which was
shown by many researchers (1, 35). Simultaneously, our data may provide
evidence for the involvement of the placental opioid system in heat
stress in a paracrine and autocrine fashion. Falconer et al. (8) have
indicated that uteroplacental -EP secretes into the maternal
circulation in response to hypoglycemic stress. Blockade of the
placental opioid system by naloxone during heat stress appears to
increase placental -EP, subsequently resulting in hypersecretion of
-EP into blood, which was indicated by increased blood -EP in
pregnant rats receiving naloxone before heat. Because naloxone
administration increased -EP in the placenta, but not in the
pituitary of pregnant rats, this appears to support the assumption of
Chan and Smith (5) that placental -EP is not involved in systemic
immunosuppression. The physiological role of placental -EP may be
different from that of pituitary -EP. Several types of opioid
receptors have been implicated in the immunosuppression (6, 10, 21),
but the type of receptor involved in stress-induced immunosuppression is not clear. Because naloxone is a nonselective opioid receptor antagonist (10, 21), further studies should be designed for determination of the types of opioid receptors involved in heat stress-induced immunosuppression during pregnancy.
Activation of the stress response inhibits the
hypothalamic-pituitary-gonadal axis at multiple levels (27, 38). CRH
suppresses secretion of luteinizing hormone-releasing hormone in the
hypothalamic arcuate nucleus either directly or indirectly via the
stimulation of -EP or corticosteroids (7, 19). In the present study, however, heat stress increased P and naloxone administration reversed it. Because progesterone-induced blocking factor administered in vivo
significantly prevented the high rates of resorption in mice treated
with antiprogesterone, progesterone-mediated suppression of lymphocyte
toxicity plays a significant role in the maintenance of pregnancy (32).
Taken together with our results showing that effects of naloxone
administration on both P and NKCA were seen only in rats exposed to
heat, activated placental hormones including P may be involved in the
immunosuppression induced by heat stress during pregnancy. However, the
effect of naloxone on E2 in rats with heat was not different from that without heat. On the basis of the
fact that stress suppresses placental functions directly or via the
opioid systems (7, 19), clarification of the involvement of increased P
during heat during pregnancy should be the focus of future work.
Perspectives
The present results regarding naloxone administration with heat in
pregnant rats indicate that the immunosuppression produced by heat
stress during pregnancy is mediated by the opioid system. Increased EP
in blood and placenta by naloxone administration only in heat-exposed
rats suggests that blockade of the placental opioid system during heat
increases placental -EP in a paracrine and autocrine fashion,
subsequently resulting in hypersecretion of -EP into blood.
Interestingly, the neurochemical relationship between CRH and the
opioid-containing systems in the hypothalamic-pituitary axis also
exists in the placenta. In placenta cells in culture, synthetic CRH
stimulates the release of -EP in a dose-dependent manner (31). The
physiological significance of the placental opioid system, especially
in relationship to placental CRH should be clarified by future studies.
We measured the alterations of -EP in the pituitary and placenta in
pregnant rats exposed to heat. Further direct evidence for the
involvement of opioid systems in heat stress-induced immunosuppression
during pregnancy would be obtained by examination of the expression of
opioid receptor mRNA in those tissues.
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ACKNOWLEDGEMENTS |
We are indebted to the president of Kanazawa University, Dr. Akira
Okada, for kind support and interest regarding this work.
| |
FOOTNOTES |
This work was supported in part by a grant-in-aid for Scientific
Research (C-07670431, C-09670382) from the Ministry of Education, Sports, Science and Culture of Japan for 1995-1998.
Address for reprint requests: H. Nakamura, Dept. of Public Health,
Kanazawa Univ. School of Medicine, Takaramachi 13-1, Kanazawa 920, Japan.
Received 7 July 1997; accepted in final form 13 November 1997.
| |
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AJP Regul Integr Compar Physiol 274(3):R672-R676
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Abstract
Introduction
