1 Department of Pharmacology, Joan and Sanford I. Weill Medical College of Cornell University, New York, New York 10021; and 2 Department of Physiology, Monash University, Clayton, Victoria, Australia 3168
![]() |
ABSTRACT |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Dynorphin A (Dyn A) stimulates the release
of ACTH in fetal sheep, a response that involves
N-methyl-D-aspartate (NMDA) receptors but not
the secretogogues corticotropin-releasing hormone or arginine vasopressin. We now find that neither Dyn A-(1-13) (0.5 mg/kg, iv)
nor NMDA (4 mg/kg, iv) elicits ACTH release in postnatal lambs. This
led us to hypothesize that Dyn A-(1-13) and NMDA might act to
release placental ACTH. However, the ability of Dyn A-(1-13), NMDA, and the -opioid receptor agonist U-50488H (1 mg/kg, iv) to
release ACTH was lost after either fetal hypophysectomy
(n = 4) or hypothalamo-pituitary disconnection
(n = 4). These results indicate that neither the
placenta nor the fetal pituitary is the site of action for these
agonists and suggest a hypothalamic or suprahypothalamic site of
action. Furthermore, the release of ACTH by Dyn A-(1-13) and NMDA
was abolished after pretreatment with indomethacin, suggesting that
they might cause the release of a prostanoid, possibly from the
placenta, that subsequently acts at the hypothalamus or serves as a
permissive factor in the action of Dyn A-(1-13) and NMDA at the hypothalamus.
-opioid receptor; hypothalamo-pituitary-adrenal axis; excitatory
amino acid; prostanoid; placenta
![]() |
INTRODUCTION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
DYNORPHIN is a naturally occurring neuropeptide found in high concentrations in the hypothalamus, the pituitary (1, 16), and, during pregnancy, the placenta (1). However, its biological function in utero is yet to be determined. Studies in fetal sheep showed that intravenous administration of dynorphin A (Dyn A)-(1-13) or Dyn A-(1-17) produces a significant increase in plasma concentrations of ACTH and cortisol (31, 32), suggesting that Dyn A may play a role in modulating hypothalamo-pituitary-adrenal (HPA) function in the fetus. Activation of the fetal HPA axis and the subsequent release of ACTH and cortisol have several effects on the fetus, such as promoting lung maturation, deposition of glycogen and brown fat, and influencing the timing and initiation of parturition.
Although Dyn A exhibits high affinity for the -opioid receptor, many
of its actions cannot be reversed by the opioid receptor antagonist
naloxone and are thought to be mediated via nonopioid mechanisms
(17, 29, 34). There is evidence to suggest that N-methyl-D-aspartate (NMDA) receptors may be
involved in these nonopioid actions of Dyn A (for review see Ref.
26). This is also true of the effects of Dyn A on the
fetal HPA axis, where ACTH release was not blocked by naloxone
(32) but was completely blocked by MK-801, a
noncompetitive NMDA receptor antagonist (27). Furthermore,
the developmental profiles of ACTH response to Dyn A-(1-13) and
NMDA are similar; neither is able to elicit ACTH release in fetal sheep
before 135 days of gestation, but both are effective secretogogues
after this time (7, 31).
This study was designed to determine the site of action of Dyn A-(1-13) and NMDA on the fetal HPA axis. Previous studies have shown that antagonists to the well known ACTH secretogogues corticotropin-releasing hormone (CRH) and arginine vasopressin (AVP) did not alter the fetal response to Dyn A-(1-13) or NMDA (27, 32). In pregnancy, the placenta is a potential site of action for Dyn A to release ACTH. ACTH is synthesized in the human placenta, and its release is regulated locally by a placental CRH-like peptide (25). The possibility that Dyn A-(1-13) and NMDA might cause release of ACTH from the placenta was suggested by the new finding presented here that the newborn lamb does not respond to either Dyn A-(1-13) or NMDA. To determine whether release of ACTH occurred from the fetal pituitary or from an extrapituitary site such as the placenta, we studied fetuses that were either intact or in which the pituitary had been removed. On finding that ACTH release was from the pituitary, we studied fetuses in which the pituitary and hypothalamus had been surgically disconnected. Our results show clearly that both Dyn A-(1-13) and NMDA release ACTH by actions within the fetal hypothalamus.
Although our results showed that ACTH release was not from the placenta, the placenta might still be important for the actions of Dyn A-(1-13) and NMDA in the fetus. Prostaglandins (PG) are released from the placenta into both maternal and fetal blood, and prostanoids have been implicated in the regulation of ACTH release. Indomethacin, a nonspecific inhibitor of prostaglandin synthases-1 and -2, inhibited the ACTH response to fever, swimming exercise, bacterial endotoxin, and interleukin-1 in rats (8, 21, 35, 37, 38). Infusion of PGE2 has been shown to elicit dose-dependent increases in ACTH in rats and fetal sheep (6, 15, 36, 38). We have therefore investigated the effect of indomethacin on Dyn A-(1-13) and NMDA release of ACTH in the fetal lamb.
![]() |
METHODS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
Animal Preparation
The hypophysectomy (HX) and hypothalamo-pituitary disconnection (HPD) experiments were conducted at Monash University in accordance with the Australian Code of Practice for the Care and Use of Animals for Experimental Purposes and were approved by the Monash University Committee for Ethics in Animal Experimentation. Aseptic surgery was performed on 12 pregnant Border-Leicester × Merino ewes at 115-119 days of pregnancy (term ~147 days). Surgery was performed under general anesthesia induced with 1 g of thiopentone sodium (iv) and maintained with 1.5% halothane administered by intermittent positive-pressure ventilation. At the time of surgery, four fetuses underwent HPD (3), four fetuses underwent HX (20), and four animals underwent a sham surgical procedure in which the pituitary was left intact and remained connected to the hypothalamus (INTACT). Vascular catheters, filled with heparin-saline, were inserted into the jugular vein and carotid artery of all of these fetuses; the maternal jugular vein was also catheterized. The fetal catheters were exteriorized via an incision in the ewe's flank. After surgery, the animals were returned to individual metabolic cages and were allowed 14 days to recover before the experiments began. The ewes were fed once daily, and water was available ad libitum.All other experiments were carried out at Weill Medical College of Cornell University. Guidelines approved by the Institution for the Care and Use of Animals were followed for all surgical procedures and experimental protocols. Aseptic surgery was carried out in pregnant sheep at 115-120 days of gestation under epidural lidocaine anesthesia supplemented with intravenous pentobarbital sodium. Indwelling catheters were placed in the fetal distal aorta and inferior vena cava as described previously (28). All animals were then allowed to deliver spontaneously at term, and fetuses were then studied again as lambs at 3-10 days of age.
Experimental Protocols
ACTH responses in fetal and postnatal lambs.
Dyn A-(1-13) (0.5 mg/kg), NMDA (4 mg/kg), or U-50488H
{trans-(±)-3,4- dichloro-N-methyl-[2-(1-pyrollidinyl)cyclohexyl]benzeneacetamide}, a selective -opioid agonist, 1 mg/kg, was administered
intravenously to three fetuses at 135-142 days of gestation
and then to the same animals as lambs at 3-10 days of age. For
animals that received more than one drug,
2 days were allowed between
studies. Blood samples (2 ml) were taken at
5, 5, 15, 30, 45, and 60 min after drug administration.
ACTH and cortisol responses in INTACT, HX, and HPD fetal lambs.
Dyn A-(1-13) (0.5 mg/kg), NMDA (4 mg/kg), or U-50488H (1 mg/kg)
was given intravenously to INTACT, HX, and HPD fetuses at 135-142
days of gestation (n = 4 each group) in a fully
orthogonal design with a minimum of 1 day between successive
experiments. The saline experiments were conducted at 142 days of
gestation. Samples (3 ml) of fetal arterial blood were taken at 15,
1, 5, 10, 15, 30, 45, 60, and 120 min after drug or saline
administration. At ~146 days of gestation, the ewe and fetus were
killed by an overdose of pentobarbital sodium given to the ewe. In all
HPD animals, completeness of the hypothalamic-pituitary disconnection was confirmed by visual inspection at postmortem. The absence of
pituitary tissue at postmortem confirmed the completeness of HX.
Fetal ACTH responses in the absence and presence of indomethacin.
Intact fetuses at 135-142 days of gestation were pretreated with
indomethacin (0.2 mg/kg) or an equivalent volume of saline 90 min
before the administration of Dyn A-(1-13) (0.5 mg/kg), NMDA (4 mg/kg), or saline (n = 4 each treatment group). When
several experiments were performed in the same animal, there was a
minimum of 2 days between successive experiments. All studies were
performed in random order. Blood samples (2 ml) were collected before
and at 5, 5, 15, 30, 45, and 60 min after Dyn A-(1-13) or saline administration and at
5, 5, 30, 60, and 120 min after NMDA administration.
Assays
All blood samples were collected into chilled tubes containing EDTA (5.58 mg) immediately after collection, and they were then centrifuged for 10 min at 3,000 g at 4°C to recover the plasma. Aliquots of the plasma (500 µl) were placed in tubes containing aprotinin (5 × 10Data Analysis
All values are presented as means ± SE. A single-factor ANOVA with repeated measures (factor = time) was used to analyze the effects of the different drugs or saline on plasma hormone levels. Tukey's test was used for post hoc analysis of significant differences. ![]() |
RESULTS |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
ACTH Responses in Fetal and Postnatal Lambs
Before drug or saline administration, plasma ir-ACTH concentrations were 40.8 ± 5.2 pg/ml in the fetuses and 123.7 ± 22.4 pg/ml in the postnatal lambs (n = 9). Figure 1 shows the peak changes in plasma ir-ACTH after intravenous administration of Dyn A-(1-13), NMDA, or U-50488H (n = 3 each drug). Maximal change in ir-ACTH was achieved 15 min after Dyn A-(1-13), and 30-60 min after NMDA and U-50488H. Administration of U-50488H elicited a similar ACTH response in both fetal and postnatal lambs, whereas Dyn A-(1-13) and NMDA had no significant effect on plasma ir-ACTH in the postnatal lambs.
|
ACTH and Cortisol Responses in HX, HPD, and INTACT Fetuses
In the INTACT fetuses, basal concentrations of ir-ACTH and ir-cortisol before drug administration were 33.0 ± 2.0 pg/ml and 12.1 ± 2.6 ng/ml, respectively, with no significant differences preceding infusion of the different drugs. In the HX fetuses, basal ir-ACTH and ir-cortisol levels were undetectable (<20 pg/ml and <2.1 ng/ml, respectively). In the HPD fetuses, plasma ir-ACTH levels (42.9 ± 4.3 pg/ml) were not significantly different from the levels in the INTACT fetuses, but ir-cortisol was undetectable. Administration of saline did not change ir-ACTH or ir-cortisol in any of the fetuses.Effects of Dyn A-(1-13)
Within 5 min of Dyn A-(1-13) administration in INTACT fetuses, plasma ir-ACTH concentrations increased from 27.9 ± 2.9 to 263.5 ± 37.5 pg/ml (P < 0.05; Fig. 2A). Plasma ir-ACTH remained significantly elevated above basal levels until 45 min after Dyn A-(1-13) administration and declined to basal levels by 120 min. Dyn A-(1-13) also caused a significant increase of ir-cortisol in the INTACT fetuses from 10.5 ± 3.0 to 21.3 ± 2.7 ng/ml after 10 min (P < 0.05), and concentrations remained elevated for 60 min (Fig. 2B). In HX fetuses, ir-ACTH and ir-cortisol remained undetectable throughout the study period. In the HPD fetuses, plasma ir-ACTH did not change significantly after Dyn A-(1-13), and plasma ir-cortisol was undetectable at all times (Fig. 2, A and B).
|
Effects of NMDA
In the INTACT fetuses, administration of NMDA resulted in an increase of plasma ir-ACTH concentrations from 29.8 ± 1.0 to 102.4 ± 26.6 pg/ml by 10 min (P < 0.05), and these concentrations remained significantly elevated until 60 min (Fig. 3A). Plasma ir-cortisol concentrations increased from 7.1 ± 2.9 to 22.1 ± 3.9 ng/ml by 10 min and remained significantly elevated for the rest of the study period (Fig. 3B). In the HX fetuses, both ir-ACTH and ir-cortisol were undetectable throughout the study period (Fig. 3). In contrast, in the HPD fetuses, NMDA administration did not change the plasma concentrations of ir-ACTH, and ir-cortisol was undetectable at all times.
|
Effects of U-50488H
In the INTACT fetuses, ir-ACTH concentrations increased from 31.4 ± 1.5 to 267.8 ± 38.8 pg/ml at 30 min after administration of the
|
Fetal ACTH Responses in the Absence and Presence of Indomethacin
Plasma ir-ACTH concentrations were similar before commencement of saline (29.0 ± 2.9 pg/ml; n = 4) or indomethacin infusion (30.8 ± 2.8 pg/ml; n = 4). Both Dyn A-(1-13) and NMDA elicited significant increases of plasma ir-ACTH concentrations by 15 min after administration (Fig. 5). Indomethacin pretreatment significantly attenuated the increase in ir-ACTH after Dyn A-(1-13) or NMDA administration (Fig. 5).
|
![]() |
DISCUSSION |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
The results of this study clearly show that the source of ACTH
released by Dyn A-(1-13), NMDA, and the -opioid agonist
U-50488H is the pituitary. The HX fetus failed to respond to all three agents. Furthermore, these agents also failed to release ACTH in
fetuses in which the hypothalamus and pituitary had been surgically disconnected. The pituitary function of HPD fetuses has been
extensively characterized. The disconnected pituitary is capable of
releasing the same amount of ACTH in response to CRH as intact fetuses
(4, 24). Furthermore, the basal concentrations and
secretory dynamics of ACTH do not differ between HPD and intact fetuses
(9). Our findings indicate that the primary site of action
of these agonists is within the fetal hypothalamus or at an
unidentified suprahypothalamic site.
This study also showed that, unlike U-50488H, Dyn A-(1-13) and NMDA were ineffective as releasers of ACTH in the postnatal lamb. This led us to suggest that these agonists might be causing release of ACTH from the placenta, a possibility that arises from the observation that the placenta of several species contains both ACTH and a CRH-like peptide (25). Whereas ACTH release was completely abolished in HX fetuses, indicating that the placenta was not the site of action of Dyn A-(1-13) and NMDA, it remained possible that a factor released from the placenta was crucial for the actions of the agonists, thus explaining the loss of efficacy of these agents after birth. Prostaglandins were considered as possible modulators of the actions of Dyn A-(1-13) and NMDA, because both the constitutive and inducible activities of PG synthases are high in the placenta (14, 19), and PGE2 has been shown to modulate the HPA axis in fetal sheep (6, 15). Furthermore, the action of PGE2 in releasing ACTH was not observed in HPD fetuses (39), suggesting, as for the data presented here for Dyn A-(1-13) and NMDA, a site of action above the pituitary.
Our data show that indomethacin significantly attenuated the ACTH
response to both Dyn A-(1-13) and NMDA, supporting a role for
prostanoids in the release of ACTH. These studies, however, do not
reveal the source or the identity of the particular prostanoid involved. Indomethacin can be expected to reduce prostanoid synthesis in the placenta as well as in the central nervous system. The lack of
effect of NMDA and DYN A-(1-13) after birth would be consistent with an effect of a placentally derived prostanoid, of which the most
likely candidate is PGE2. PGE2 is
quantitatively the most important prostanoid in fetal plasma, and it is
derived primarily from the placenta. PGE2 is also the most
potent known ACTH-releasing factor in the fetus. However, studies in
the rat have shown that multiple prostanoids (PGE1,
-E2, and -F2) may be involved in ACTH
release (23). It is unlikely that Dyn A-(1-13) and
NMDA caused sufficient release of prostanoids from the placenta to elicit ACTH by actions within the hypothalamus. Alternatively, PGE2 released from the placenta may serve as a permissive
factor for the direct action of Dyn A-(1-13) on NMDA receptors in
the hypothalamus. PGE2 has been reported to augment
hyperalgesia elicited by NMDA in the spinal cord (18).
Our finding that Dyn A-(1-13) was acting at either the
hypothalamus or a suprahypothalamic site was surprising, as it was not
expected that a peptide of 13 amino acids would distribute to the brain
so rapidly after intravenous administration. Peak ACTH levels were
observed 5 min after Dyn A-(1-13) administration in the present
studies. If Dyn A-(1-13) does reach the hypothalamus, it would be
expected to act on -opioid receptors as well as on NMDA receptors.
However, it was shown that naloxone does not attenuate the release of
ACTH in the fetus in response to Dyn A-(1-13) (32). One possible explanation is that a degradative fragment of Dyn A-(1-13) is responsible for the action on the HPA axis. In vitro studies using human blood showed that Dyn A-(1-13) is truncated to
Dyn A-(1-12) and Dyn A-(2-13) within 1 min, and then to Dyn A-(2-12), Dyn A-(3-12), and Dyn A-(4-12) within 2-3
min (11, 22). The NH2-terminal tyrosine is
required for binding to opioid receptors. Dyn A-(2-13) is devoid
of opioid actions but can elicit many of the nonopioid actions of Dyn
A-(1-13) that involve the NMDA receptor, including hindlimb
paralysis, barrel rolling, antinociception, decreases in spinal cord
blood flow, and suppression of opioid tolerance and dependence
(17, 29, 34). Although Dyn A-(1-13) degradation has
not been determined in vivo, especially in the fetal sheep, it is
possible that one or more of these degradative fragments may be the
active peptide at the presumed hypothalamic (or suprahypothalamic) site
in fetal sheep. We have previously shown that Dyn A-(2-13) elicits
ACTH release in fetal sheep (32), and Dyn A-(2-13)
may be degraded to even shorter fragments in vivo.
A hypothalamic site of action for NMDA is more easily understood. The NMDA receptor has been located on the hypothalamus of the fetal and adult rat (13), and there is a marked increase in the number of NMDA-binding sites in the hypothalamus of fetal sheep from ~135 days of gestation (2). In addition, NMDA elicits luteinizing hormone (LH) release in fetal sheep (5, 7), but direct addition of NMDA to primary cultures of fetal sheep anterior pituitary cells failed to elicit the release of LH (5). NMDA also failed to cause the release of ACTH from murine anterior pituitary AtT-20 cells (10).
The interaction between Dyn A-(1-13) and NMDA receptors is not well understood. A high-affinity binding site for [125]Dyn A-(2-17) has been shown for rat brain, where binding was modulated by ligands for the glutamate, glycine, polyamine, and channel sites of the NMDA receptor (30). It is noteworthy that these interactions were shown to occur at only relatively high concentrations of dynorphin. Our previous observation (27) that the release of ACTH by Dyn A-(1-13) in the fetus is blocked by MK-801 indicates that the peptide interacts with a site within the ion channel of the NMDA receptor. It is possible that dynorphin may stimulate the release of glutamate in the hypothalamus; this would readily explain why both competitive and noncompetitive NMDA antagonists have been reported to block the nonopioid actions of dynorphin peptides. Both Dyn A-(1-17) and Dyn A-(2-17) markedly increase extracellular levels of glutamate and aspartate in the rat hippocampus (12).
In summary, we have shown that Dyn A-(1-13) and NMDA elicit ACTH release in fetal, but not postnatal, sheep, a response that involves actions within the fetal central nervous system and that is modulated by prostaglandin synthesis. The exact mechanism by which Dyn A-(1-13) and NMDA induce ACTH release in the fetal sheep, and the loss of responsiveness after birth, remain to be determined.
![]() |
ACKNOWLEDGEMENTS |
---|
We thank Alex Satragno (Monash University) for surgical support, and Joseph Fasolo (Weill Medical College of Cornell University) for technical support.
![]() |
FOOTNOTES |
---|
This work was supported by a grant from the National Institute on Drug Abuse (R37-DA-02475).
Address for reprint requests and other correspondence: H. H. Szeto, Dept. of Pharmacology, Weill Medical College of Cornell University, 1300 York Ave., New York, NY 10021 (E-mail: hhszeto{at}med.cornell.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
First published February 26, 2002;10.1152/ajpendo.00527.2001
Received 26 November 2001; accepted in final form 18 February 2002.
![]() |
REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1.
Ahmed, MS,
Randall LW,
Sibai B,
Dass C,
Fridland G,
Desiderio DM,
and
Tolun E.
Identification of dynorphin 1-8 in human placenta by mass spectrometry.
Life Sci
40:
2067-2076,
1987[ISI][Medline].
2.
Anderson, KJ,
Mason KL,
McGraw TS,
Theophilopoulos DT,
Sapper MS,
and
Burchfield DJ.
The ontogeny of glutamate receptors and D-aspartate binding sites in the ovine CNS.
Brain Res Dev Brain Res
118:
69-77,
1999[ISI][Medline].
3.
Antolovich, GC,
Clarke IJ,
McMillen IC,
Perry RA,
Robinson PM,
Silver M,
and
Young R.
Hypothalamo-pituitary disconnection in the fetal sheep.
Neuroendocrinology
51:
1-9,
1990[ISI][Medline].
4.
Antolovich, GC,
McMillen IC,
Robinson PM,
Silver M,
Young IR,
and
Perry RA.
The effect of hypothalamo-pituitary disconnection on the functional and morphologic development of the pituitary-adrenal axis in the fetal sheep in the last third of gestation.
Neuroendocrinology
54:
254-261,
1991[ISI][Medline].
5.
Bettendorf, M,
de Zegher F,
Albers N,
Hart CS,
Kaplan SL,
and
Grumbach MM.
Acute N-methyl-D,L-aspartate administration stimulates the luteinizing hormone releasing hormone pulse generator in the ovine fetus.
Horm Res
51:
25-30,
1999[ISI][Medline].
6.
Brooks, AN.
Prostaglandin E2 stimulates adrenocorticotrophin and cortisol secretion via a hypothalamic site of action in fetal sheep.
J Dev Physiol
18:
173-177,
1992[ISI][Medline].
7.
Brooks, AN,
and
Howe DC.
Adrenocorticotrophin and luteinizing hormone responses to N-methyl-D-aspartate during fetal development in sheep.
J Neuroendocrinol
8:
315-321,
1996[ISI][Medline].
8.
Buller, KM,
Xu Y,
and
Day TA.
Indomethacin attenuates oxytocin and hypothalamic-pituitary-adrenal axis responses to systemic interleukin-1 beta.
J Neuroendocrinol
10:
519-528,
1998[ISI][Medline].
9.
Canny, BJ,
Young IR,
and
Veldhuis JD.
Hypothalamo-pituitary disconnection of the late-gestation ovine fetus results in profound changes in cortisol secretion that are not reflected in commensurate changes in adrenocorticotropin secretion.
Endocrinology
139:
3210-3219,
1998
10.
Cheng, PY,
Birk AV,
Gershengorn MC,
and
Szeto HH.
Dynorphin stimulates corticotropin release from mouse anterior pituitary AtT-20 cells through nonopioid mechanisms.
Neuroendocrinology
71:
170-176,
2000[ISI][Medline].
11.
Chou, JZ,
Chait BT,
Wang R,
and
Kreek MJ.
Differential biotransformation of dynorphin A(1-17) and dynorphin A(1-13) peptides in human blood, ex vivo.
Peptides
17:
983-990,
1996[ISI][Medline].
12.
Faden, AI.
Dynorphin increases extracellular levels of excitatory amino acids in the brain through a nonopioid mechanism.
J Neurosci
12:
425-429,
1992[Abstract].
13.
Ghosh, PK,
Baskaran N,
and
van den Pol AN.
Developmentally regulated gene expression of all eight metabotropic glutamate receptors in hypothalamic suprachiasmatic and arcuate nucleia PCR analysis.
Dev Brain Res
102:
1-12,
1997[ISI][Medline].
14.
Gibb, W,
Matthews SG,
and
Challis JR.
Localization and developmental changes in prostaglandin H synthase (PGHS) and PGHS messenger ribonucleic acid in ovine placenta throughout gestation.
Biol Reprod
54:
654-659,
1996[Abstract].
15.
Hollingworth, SA,
Deayton JM,
Young IR,
and
Thorburn GD.
Prostaglandin E2 administered to fetal sheep increases the plasma concentration of adrenocorticotropin (ACTH) and the proportion of ACTH in low molecular weight forms.
Endocrinology
136:
1233-1240,
1995[Abstract].
16.
Hollt, V,
Haarmann I,
Bovermann K,
Jerlicz M,
and
Herz A.
Dynorphin-related immunoreactive peptides in rat brain and pituitary.
Neurosci Lett
18:
149-153,
1980[ISI][Medline].
17.
Hooke, LP,
He L,
and
Lee NM.
[Des-Tyr1]dynorphin A-(2-17) has naloxone-insensitive antinociceptive effect in the writhing assay.
J Pharmacol Exp Ther
273:
802-807,
1995[Abstract].
18.
Malmberg, AB,
and
Yaksh TL.
Hyperalgesia mediated by spinal glutamate or substance P receptor blocked by spinal cyclooxygenase inhibition.
Science
257:
1276-1279,
1992[ISI][Medline].
19.
McLaren, WJ,
Young IR,
Wong MH,
and
Rice GE.
Expression of prostaglandin G/H synthase-1 and -2 in ovine amnion and placenta following glucocorticoid-induced labour onset.
J Endocrinol
151:
125-135,
1996[Abstract].
20.
Mesiano, S,
Young IR,
Baxter RC,
Hintz RL,
Browne CA,
and
Thorburn GD.
Effect of hypophysectomy with and without thyroxine replacement on growth and circulating concentrations of insulin-like growth factors I and II in the fetal lamb.
Endocrinology
120:
1821-1830,
1987[Abstract].
21.
Morimoto, A,
Murakami N,
Nakamori T,
Sakata Y,
and
Watanabe T.
Possible involvement of prostaglandin E in development of ACTH response in rats induced by human recombinant interleukin-1.
J Physiol
411:
245-256,
1989[Abstract].
22.
Müller, S,
and
Hochhaus G.
Metabolism of dynorphin A 1-13 in human blood and plasma.
Pharm Res
12:
1165-1170,
1995[ISI][Medline].
23.
Nasushita, R,
Watanabe H,
and
Takebe K.
A comparative study of adrenocorticotropin-releasing activity of prostaglandins E1, E2, F2alpha and D2 in the rat.
Prostaglandins Leukot Essent Fatty Acids
56:
165-168,
1997[ISI][Medline].
24.
Ozolins, IZ,
Young IR,
and
McMillen IC.
Effect of cortisol infusion on basal and corticotropin-releasing factor (CRF)-stimulated plasma ACTH concentrations in the sheep fetus after surgical isolation of the pituitary.
Endocrinology
127:
1833-1840,
1990[Abstract].
25.
Petraglia, F,
Sawchenko PE,
Rivier J,
and
Vale W.
Evidence for local stimulation of ACTH secretion by corticotropin-releasing factor in human placenta.
Nature
328:
717-719,
1987[ISI][Medline].
26.
Shukla, VK,
and
Lemaire S.
Non-opioid effects of dynorphins: possible role of the NMDA receptor.
Trends Pharmacol Sci
15:
420-424,
1994[ISI][Medline].
27.
Szeto, HH,
Soong Y,
and
Wu D.
The role of N-methyl-D-aspartate receptors in the release of adrenocorticotropin by dynorphin A 1-13.
Neuroendocrinology
69:
28-33,
1999[ISI][Medline].
28.
Szeto, HH,
Zhu YS,
and
Cai LQ.
Central opioid modulation of fetal cardiovascular function: role of µ- and -receptors.
Am J Physiol Regulatory Integrative Comp Physiol
258:
R1453-R1458,
1990
29.
Takemori, AE,
Loh HH,
and
Lee NM.
Suppression by dynorphin a and [des-tyr1]dynorphin a peptides of the expression of opiate withdrawal and tolerance in morphine-dependent mice.
J Pharmacol Exp Ther
266:
121-124,
1993[Abstract].
30.
Tang, Q,
Gandhoke R,
Burritt A,
Hruby VJ,
Porreca F,
and
Lai J.
High-affinity interaction of (des-Tyrosyl)dynorphin A(2-17) with NMDA receptors.
J Pharmacol Exp Ther
291:
760-765,
1999
31.
Taylor, CC,
Wu DL,
Soong Y,
Yee J,
and
Szeto HH.
Differential mechanisms of ovine fetal pituitary stimulation by a selective kappa-opioid agonist and by dynorphin.
Neuroendocrinology
64:
419-424,
1996[ISI][Medline].
32.
Taylor, CC,
Wu DL,
Soong Y,
Yee J,
and
Szeto HH.
Dynorphin A-(1-13) stimulates ovine fetal pituitary-adrenal function through a novel non-opioid mechanism.
J Pharmacol Exp Ther
280:
416-421,
1997
33.
Taylor, CC,
Wu DL,
Soong Y,
Yee JS,
and
Szeto HH.
kappa-Opioid agonist, U-50488H, stimulates ovine fetal pituitary-adrenal function via hypothalamic arginine-vasopressin and corticotrophin-releasing factor.
J Pharmacol Exp Ther
277:
877-884,
1996[Abstract].
34.
Walker, JM,
Moises HC,
Coy DH,
Baldrighi G,
and
Akil H.
Nonopiate effects of dynorphin and des-Tyr-dynorphin.
Science
218:
1136-1138,
1982[ISI][Medline].
35.
Watanabe, T,
Clark WG,
Ceriani G,
and
Lipton JM.
Elevation of plasma ACTH concentration in rabbits made febrile by systemic injection of bacterial endotoxin.
Brain Res
652:
201-206,
1994[ISI][Medline].
36.
Watanabe, T,
Morimoto A,
Morimoto K,
Nakamori T,
and
Murakami N.
ACTH release induced in rats by noradrenaline is mediated by prostaglandin E2.
J Physiol
443:
431-439,
1991[Abstract].
37.
Watanabe, T,
Morimoto A,
and
Murakami N.
ACTH response in rats during biphasic fever induced by interleukin-1.
Am J Physiol Regulatory Integrative Comp Physiol
261:
R1104-R1108,
1991[Abstract].
38.
Watanabe, T,
Morimoto A,
Sakata Y,
Long NC,
and
Murakami N.
Prostaglandin E2 is involved in adrenocorticotrophic hormone release during swimming exercise in rats.
J Physiol
433:
719-725,
1991[Abstract].
39.
Young, IR,
Loose JM,
Kleftogiannis F,
and
Canny BJ.
Prostaglandin E2 acts via the hypothalamus to stimulate ACTH secretion in the fetal sheep.
J Neuroendocrinol
8:
713-720,
1996[ISI][Medline].
|
HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
Visit Other APS Journals Online |