Abstract
The opioid-like peptide nociceptin/orphanin FQ (N/OFQ) produces marked cardiovascular and renal responses after central or peripheral administration in rats. Due to their ability to behave as full/partial agonists or antagonists in different cellular and tissue assays, the present studies were performed to determine how compounds classified as N/OFQ peptide (NOP) receptor partial agonists ([F/G]N/OFQ(1-13)-NH2, Ac-RYYRIK-NH2, and Ac-RYYRWK-NH2) affect cardiovascular and renal function in vivo. In conscious Sprague-Dawley rats, intracerebroventricular (i.c.v.) administration of each of the three NOP receptor ligands produced profound cardiovascular (depressor), renal excretory (water diuresis), and renal sympathetic nerve activity (inhibitory) responses that were similar to those produced by i.c.v. injection of the native ligand N/OFQ. In contrast, in other groups of rats, the intravenous (i.v.) bolus injection of these same NOP receptor ligands produced responses unlike N/OFQ; N/OFQ evoked an immediate and profound bradycardia and hypotension with no change in urine output, whereas all purported NOP receptor partial agonists elicited a subtle slow onset hypotension, no change in heart rate, and a marked water diuresis. In other studies, i.v. bolus pretreatment of rats with NOP receptor partial agonists prevented/attenuated the cardiovascular depressor effects produced by a subsequent i.v. bolus N/OFQ challenge without affecting the cardiovascular responses to i.c.v. N/OFQ. Together, these findings demonstrate that in conscious rats, NOP receptor partial agonists produce functionally selective effects on cardiovascular and renal function ranging from full agonist (i.c.v., cardiovascular depressor; i.c.v. and i.v., water diuresis), partial agonist (i.v., submaximal hypotension) to antagonist (i.v., blockade of N/OFQ-evoked bradycardia and hypotension) behavior.
Nociceptin/orphanin FQ (N/OFQ), an opioid-like peptide containing 17 amino acids, is the endogenous ligand for the N/OFQ peptide (NOP; also referred to as opioid receptor-like 1 peptide) receptor (Meunier et al., 1995; Reinscheid et al., 1995; Cox et al., 2000). N/OFQ has a high degree of structural similarity to that of endogenous opioid peptides with particular resemblance to dynorphin A(1-17), the native κ opioid peptide receptor ligand (Civelli et al., 1997). Despite sequence similarity, N/OFQ has no appreciable affinity for classical opioid receptors and instead selectively activates its own NOP receptors (Meunier et al., 2000). Upon activating NOP receptors N/OFQ modulates second messenger pathways via Gi/o to alter neurotransmitter and hormonal release and to elicit organ responses at central and peripheral levels (Hawes et al., 2000).
N/OFQ produces marked changes in cardiovascular and renal function in conscious or anesthetized rats (Kapusta, 2000; Salis et al., 2000; Malinowska et al., 2002). In this regard, intracerebroventricular (i.c.v.) injection of N/OFQ produces a dose-dependent bradycardia, hypotension, diuresis, and antinatriuresis (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999; Shirasaka et al., 1999). The cardiovascular depressor responses elicited by central N/OFQ occur shortly after administration (15 s–1 min) and are prolonged in duration (30–40 min). Central N/OFQ also evokes a concurrent and sustained (70–80 min) increase in urine flow rate and decrease in urinary sodium excretion; however, this free water diuresis is delayed in onset, commencing after arterial blood pressure and heart rate return to control levels (i.e., approximately 30 min after i.c.v. peptide injection) (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999). In comparison with these centrally evoked responses, i.v. bolus N/OFQ also produces a dose-dependent hypotension that occurs with bradycardia and not a baroreflex-evoked tachycardia (Champion et al., 1997; Champion and Kadowitz, 1997; Bigoni et al., 1999; Madeddu et al., 1999; Kapusta, 2000; Malinowska et al., 2000a, 2002). However, these cardiovascular depressor responses are immediate in onset and of brief duration (3–10 min). Although it remains to be fully determined, the results of pilot studies suggest that i.v. bolus N/OFQ may not affect urine output (D. R. Kapusta, unpublished). Thus, the particular profile/pattern of cardiovascular and renal responses evoked by N/OFQ depends on the route in which this peptide is administered (i.c.v. versus i.v. bolus), presumably reflecting the different tissue/cell types that N/OFQ comes in contact with after distribution.
Since the discovery of N/OFQ, considerable effort has been made to develop new ligands that bind selectively to but do not activate NOP receptors. These antagonist compounds are required to study the importance of the endogenous N/OFQ system in different biological processes. However, certain ligands that have been reported to have NOP receptor antagonist behavior have also been shown to exert additional pharmacological properties in different assays/preparations. For example, the compounds [Phe1ψ(CH2-NH)Gly2]N/OFQ-(1-13)-NH2 ([F/G]; Guerrini et al., 1998), Ac-RYYRIK-NH2 (HEX 1), and Ac-RYYRWK-NH2 (HEX 2; Dooley et al., 1997) behave as full agonists, partial agonists, or antagonists of NOP receptors, depending on the in vitro or in vivo system studied (Calo' et al., 2000). Despite their mixed pharmacological profiles, these compounds continue to be classified and referred to (as they are herein) as “partial agonists” of the NOP receptor (Calo' et al., 2000). Despite their unique and cellular/tissue/system-dependent pharmacological profile, it remains to be established how NOP receptor partial agonists affect cardiovascular and renal function in conscious rats compared with the native ligand N/OFQ. This is of particular interest since NOP receptors that are expressed in both central (brain and spinal cord) and peripheral tissues (vasculature, kidneys, heart, sympathetic, and parasympathetic nerve terminals) (Mollereau and Mouledeous, 2000; Malinowska et al., 2001, 2000b) may be affected differently by various classes of NOP receptor ligands (e.g., N/OFQ and NOP receptor partial agonists) to influence cardiovascular and renal function.
With these considerations, the present studies examined the cardiovascular and renal responses produced by the central and peripheral administration of NOP receptor partial agonists in vivo. In particular, we compared the cardiovascular, renal excretory, and renal sympathetic nerve responses produced by the i.c.v. (central) and i.v. bolus (peripheral) administration of N/OFQ or NOP receptor partial agonists in conscious Sprague-Dawley rats. The three partial agonists tested were [F/G], HEX 1, and HEX 2. Considering that these NOP receptor partial agonists can prevent the biological activities of N/OFQ in certain in vitro and in vivo systems (Calo' et al., 1998, 2000), additional studies were performed to determine how the i.v. bolus pretreatment of conscious rats with these NOP receptor ligands modified the cardiovascular responses to a subsequent i.v. bolus N/OFQ challenge.
Materials and Methods
Subjects
Male Sprague-Dawley rats (275–325 g; Harlan, Indianapolis, IN) were used in these studies. Rats were fed with normal sodium diets (Na+ content, 163 mEq/kg) and were allowed tap water ad libitum. All procedures were conducted in accordance with the National Institutes of Health guidelines for the Care and Use of Animals and were approved by the Louisiana State University Health Sciences Center Institutional Animal Care and Use Committee.
Surgery
For experiments requiring the i.c.v. administration of drugs, a stainless steel cannula was stereotaxically implanted into the right lateral cerebral ventricle of rats anesthetized with ketamine (40 mg/kg, i.m.; Vedco Inc., St. Joseph, MO) in combination with xylazine (5 mg/kg, i.m.; Butler, Columbus, OH) at least 5 to 7 days before experimentation. The coordinates used to position the cannula were 0.3 mm posterior to the bregma, 1.3 mm lateral to midline, and 4.5 mm below skull surface (Paxinos and Watson, 1986). Verification of cannula position in the lateral ventricle was made by observation of cerebrospinal fluid flow from the implanted steel cannula after removal of the obturator or by observing injected dye in the lateral ventricle after completion of the study and subsequent postmortem brain section (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999).
On the day of the study, rats were anesthetized with sodium methohexital (75 mg/kg, i.p., and supplemented with 10 mg/kg, i.v., as needed; King Pharmaceuticals, Bristol, TN) and instrumented with chronic catheters in the left femoral artery and vein (PE-10 connected to PE-50; BD Biosciences, Sparks, MD) and urinary bladder (flanged PE-240; BD Biosciences) for measurement of arterial blood pressure, administration of drugs/saline, and collection of urine, respectively. In certain studies, the rat (still anesthetized) was also implanted with a recording electrode (bipolar platinum wire; Cooner Wire Company, Chatsworth, CA) to a renal nerve branch to measure renal sympathetic nerve activity by using standard techniques described previously (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999).
After surgical preparation, rats were placed in a rat holder (a chamber with Plexiglas ends connected by stainless steel rods) that permits forward and backward movement of the rat, allows for collection of urine, and when appropriate protects the renal nerve recording preparation. An i.v. infusion of isotonic saline (55 μl/min) was then started and continued for the duration of the experiment. The experimental protocol commenced after rats regained full consciousness and cardiovascular and renal excretory function stabilized. Heart rate was derived from the pulse pressure with a tachograph (model 7 P4H; Grass Instruments, Quincy, MA). Heart rate and arterial pressure were continuously monitored and recorded on a Grass polygraph (model 7).
Experimental Protocols
Intracerebroventricular Microinjection Studies. Studies were performed to determine the cardiovascular and renal excretory responses produced by the i.c.v. microinjection (i.e., central nervous system administration) of N/OFQ or NOP receptor partial agonists in conscious rats. In certain animals, changes in renal sympathetic nerve activity were also measured. After stabilization of cardiovascular and renal excretory function (4–6 h), urine was collected during a 20-min control period. Groups of conscious rats then received i.c.v. microinjection of one of the NOP receptor partial agonists: HEX 1 (1 nmol = 1 μg; n = 5), HEX 2 (0.73 nmol = 1 μg; n = 6), or [F/G] (7.3 nmol = 10 μg; n = 9). For comparative purposes, other groups of rats received either i.c.v. injection of the endogenous ligand N/OFQ (5.5 nmol = 10 μg, i.c.v.) or isotonic saline vehicle (5 μl). Immediately after i.c.v. microinjection of drug/vehicle, urine was collected for 80 min during eight consecutive 10-min experimental urine samples.
The i.c.v. doses of NOP receptor ligands used in the current studies were based on the following observations. In previous i.c.v. doseresponse studies performed under similar experimental conditions, we have established that N/OFQ administered to rats over a range of 0.55, 5.5, and 16.5 nmol produced relatively comparable cardiovascular depressor responses, but a maximal diuresis at the 5.5-nmol (10-μg) dose (Kapusta et al., 1997). Similarly, in i.c.v. dose-response studies with [F/G], we have shown that a dose of 7.3 nmol (10 μg) was the minimally effective dose to produce marked changes in cardiovascular and renal function. Thus, dose-response studies with N/OFQ and [F/G] were not repeated, and the 5.5- and 7.3-nmol i.c.v. doses of N/OFQ and [F/G], respectively, were used in the current studies. In pilot i.c.v. dose-response studies, it was then established that HEX 1 and HEX 2 were considerably more potent than either N/OFQ or [F/G] in altering cardiovascular and renal function. Based on findings of these studies it was determined that the minimally effective i.c.v. dose of HEX 1 and HEX 2 to produce marked changes in cardiovascular and renal function was 1 nmol (1 μg) and 0.73 nmol (1 μg), respectively. In each of the i.c.v. dose-response studies noted above, it was observed that higher i.c.v. doses of each NOP receptor ligand produced a qualitatively similar pattern of cardiovascular depressor and water diuretic properties, thus demonstrating that i.c.v. dose responsiveness was not bimodal. However, at doses higher than those used in the current studies each NOP receptor ligand often produced sedation.
Single Dose Intravenous Bolus Studies. Studies were performed to determine the cardiovascular, renal excretory, and in certain studies the renal sympathetic nerve activity responses produced by the i.v. bolus injection (i.e., peripheral administration) of N/OFQ or NOP receptor partial agonists of conscious rats. After equilibration and collection of a control urine sample (20 min), groups of rats received an i.v. bolus injection of one of the following NOP receptor partial agonists: HEX 1 (100 nmol/kg; n = 6), HEX 2 (100 nmol/kg; n = 6), or [F/G] (900 nmol/kg; n = 6). For comparative purposes, other groups of rats received either an i.v. bolus injection of the endogenous ligand N/OFQ (30 or 100 nmol/kg) or isotonic saline vehicle (200 μl). Immediately after i.v. bolus drug/vehicle injection, urine was collected for 80 min during eight consecutive 10-min experimental urine samples.
The doses for HEX 1 (100 nmol/kg), HEX 2 (100 nmol/kg), and [F/G] (900 nmol/kg) used in the single dose i.v. bolus studies were selected based on results of pilot studies that demonstrated that these were the minimally effective doses of each NOP receptor ligand to produce a significant increase in urine flow rate and decrease in urinary sodium excretion. N/OFQ was administered at 30 or 100 nmol/kg, i.v., since we and other investigators have previously shown that at these doses N/OFQ elicits immediate and profound cardiovascular depressor responses.
Intravenous Bolus Dose-Response Studies with HEX 1. Additional studies were performed to explore the full i.v. bolus dose-response relationship of the NOP receptor partial agonist HEX 1 on cardiovascular and renal function. For these studies, the same experimental protocol as described above for the single i.v. bolus dose HEX 1 (100 nmol/kg) study was repeated, with the exception that groups of rats received HEX 1 at i.v. bolus doses of 30 (n = 4), 300 (n = 5), or 900 (n = 5) nmol/kg.
Cardiovascular Antagonist Studies. Studies were performed to determine whether i.v. bolus pretreatment of conscious rats with the NOP receptor ligands HEX 1, HEX 2, or [F/G] modified the cardiovascular responses to a subsequent i.v. bolus N/OFQ challenge. Renal excretory function was not measured in these studies. After stabilization, baseline (control) cardiovascular (heart rate, pulsatile, and mean arterial pressure) function was measured for 20 min. Rats then received an i.v. bolus pretreatment (200 μl) of the NOP receptor ligand HEX 1 (100 nmol/kg; n = 8), HEX 2 (100 nmol/kg; n = 6), [F/G] (900 nmol/kg; n = 6), or isotonic saline vehicle (n = 6). After 5-min drug/vehicle distribution, the rats then received an i.v. bolus injection of N/OFQ (100 nmol/kg for studies with HEX 1, HEX 2, or saline pretreatment; 30 nmol/kg for studies with [F/G] or saline pretreatment). The cardiovascular responses evoked by the i.v. bolus N/OFQ challenge were then measured for 15 min. In other studies, the cardiovascular responses to i.v. bolus N/OFQ (100 nmol/kg) were examined in separate rats pretreated with HEX 1 or HEX 2 (100 nmol/kg, i.v.) for longer pretreatment times (30 or 60 min). The i.v. bolus pretreatment doses for NOP receptor partial agonists used in these studies were derived from pilot studies and in the cases of HEX 2 and [F/G] were shown to be the minimally effective doses of each ligand to significantly increase urine output.
Analytic Procedures. Urine volume was determined gravimetrically. Urine sodium concentration was measured by flame photometry (model 943; Instrumentation Laboratories, Lexington, MA). Data acquisition for renal sympathetic nerve activity measurements was performed with a commercially available software package (Acknowledge for Windows; Biopac Inc., Santa Barbara, CA). Integrated renal sympathetic nerve activity was expressed as microvolt-seconds per 1-s intervals. For each 10-min experimental period, the values for integrated renal sympathetic nerve activity were sampled over the entire collection period, and the numbers were averaged. Because of the limitations of comparing values for multifiber renal sympathetic nerve activity between animals, the data are expressed as a percentage of control with the control values for each animal taken as 100% (Kapusta and Kenigs, 1999; Kapusta et al., 1999, 2002).
Drugs. N/OFQ was obtained from Phoenix Pharmaceuticals (Belmont, CA). HEX 1, HEX 2, and [F/G] were synthesized and provided by the laboratories of Professors R. Guerrini and S. Salvadori (Department of Pharmaceutical Sciences, University of Ferrara, Ferrara, Italy). Stock solutions of N/OFQ and NOP receptor partial agonists used for i.v. and i.c.v. administration were prepared fresh in isotonic saline and stored frozen. Injection of drugs in isotonic saline vehicle (5 μl) into the lateral cerebroventricle of conscious rats was made via a 10-μl Hamilton syringe (Hamilton, Reno, NV).
Data Analysis
Data are expressed as means ± standard error of the mean of n experiments. Statistical comparisons were made as follows. A nonrepeated one-way analysis of variance and post hoc Dunnett's multiple comparison test were used to compare peak changes (Δ) in cardiovascular and renal function which were produced by different NOP receptor ligands in separate groups of animals from the control group (vehicle) value. For two groups, this comparison was made by Student's t test for paired and unpaired observations as appropriate. In the time-course study, changes in physiological parameters at different time points within a group were compared with respective group control values by using a one-way analysis of variance for repeated measures and post hoc Dunnett's multiple comparison test. In each case, a p value <0.05 was considered to be significant.
Results
We have previously reported that, in conscious rats, the i.c.v. microinjection of 5.5 nmol of N/OFQ produces bradycar- dia, hypotension, renal sympathoinhibition, and water diuresis (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999).
Figure 1 depicts the peak changes in cardiovascular and renal excretory function produced by the i.c.v. injection of N/OFQ (5.5 nmol = 10 μg) and each of the purported NOP receptor partial agonists, [F/G] (7.3 nmol = 10 μg), HEX 1 (1.0 nmol = 1 μg), or HEX 2 (0.73 nmol = 1 μg) in conscious Sprague-Dawley rats (see “Experimental Protocols” for basis for drug doses). Cardiovascular and renal excretory function was measured in each rat during control (predrug baseline values for each animal) and immediately after i.c.v. drug injection for 80 min (consecutive 10-min experimental periods). Group data are peak (mean ± S.E.) changes from control in each cardiovascular and renal parameter that occurred over the 80-min period after the i.c.v. injection of isotonic saline vehicle, N/OFQ, or each NOP receptor ligand.
As illustrated (Fig. 1), the i.c.v. injection of isotonic saline vehicle failed to alter any cardiovascular or renal excretory parameter over the course of the experiment (80 min). In contrast, in conscious rats, i.c.v. injection of N/OFQ as well as [F/G], HEX 1, and HEX 2 each produced significant decreases in heart rate, mean arterial pressure, and urinary sodium excretion and a profound increase in urine flow rate. Although not depicted, the pattern and magnitude of cardiovascular (onset, approx. 30 s to 2 min; peak nadir, 10–20 min; duration, 40–50 min) and renal responses (onset, approx. 30 min; peak, 40–50 min; duration, 70–80 min) produced by the i.c.v. injection of [F/G], HEX 1, and HEX 2 were highly comparable and essentially the same as those produced by N/OFQ in this and previous studies (Kapusta et al., 1997, 1999). Similar to i.c.v. N/OFQ, it was also confirmed that the central injection of each of the three purported NOP receptor partial agonists inhibited renal sympathetic nerve activity (data not shown). In the current studies, HEX 1 and HEX 2 were each administered at a lower dose of 1.0 μg (1.0 and 0.73 nmol, respectively) because preliminary findings revealed that the i.c.v. injection of 10-fold higher doses produced marked sedation. However, at these higher doses each NOP receptor ligand still produced cardiovascular, renal excretory and renal sympathetic nerve activity responses that were similar in pattern/direction as those elicited by i.c.v. N/OFQ (Kapusta et al., 1997, 1999, 2002; Kapusta and Kenigs, 1999; Kapusta, 2000).
Figure 2 depicts the peak changes in cardiovascular (Fig. 2, A and B) and renal excretory function (Fig. 2C) produced by the i.v. bolus injection of N/OFQ and the purported NOP receptor partial agonists in conscious Sprague-Dawley rats. Cardiovascular and renal function was measured in each rat during control and immediately after i.v. bolus drug injection for 80 min (consecutive 10-min experimental periods). In these studies, it was demonstrated that there were differences in time to onset and peak effects for N/OFQ (rapid onset and short duration) versus the other NOP receptor ligands (slow onset and long duration). As such, cardiovascular data are presented as peak changes (mean ± S.E.) from control that occurred within the first 10 min immediately after i.v. bolus drug/saline injection (Fig. 2A) and the peak changes that were observed over the remaining 70-min protocol (Fig. 2B; time points, 20–80 min). As shown in Fig. 2C, data for urine flow rate and urinary sodium excretion are the peak changes from predrug baseline control that occurred over the entire 80-min study (consecutive 10-min periods).
Baseline cardiovascular and renal function in groups of rats treated with N/OFQ or each NOP receptor partial agonists (Fig. 2, A–C) were not significantly different from those observed in isotonic saline-treated animals (HR, 417 ± 16 bpm; MAP, 117 ± 5 mm Hg; V, 54 ± 8 μl/min; UNaV, 8.3 ± 0.6 μEq/min). After i.v. bolus injection, 100 nmol/kg N/OFQ produced an immediate and marked reduction in heart rate and mean arterial pressure (Fig. 2A), with these responses returning to, and remaining at, predrug control levels approximately 10 min postinjection (Fig. 2B). In comparison with N/OFQ, the i.v. bolus injection of [F/G] (900 nmol/kg), HEX 1 (100 nmol/kg), or HEX 2 (100 nmol/kg) produced a substantially different cardiovascular response profile. For instance, each of these three NOP receptor ligands failed to produce an immediate and marked bradycardia or hypotension after i.v. bolus injection (Fig. 2A). In fact, at this dose (100 nmol/kg, i.v.) these ligands did not significantly alter baseline cardiovascular function over the first 10 min after administration. However, by approximately 10 to 15 min after injection, each of these ligands produced a subtle (but statistically significant) hypotensive response (ranging from 10 to 20 mm Hg) that persisted for 60 to 70 min (Fig. 2B; periods 10–80 min; see Fig. 3 for time-course data for HEX 1). Figure 2C demonstrates that N/OFQ and the purported NOP receptor partial agonists also differed in their ability to affect urine output but not urinary sodium excretion. Thus, i.v. N/OFQ failed to increase urine flow rate over the entire experimental period (80 min) at this (100 nmol/kg) or other doses (10, 30, or 300 nmol/kg; data not shown) tested. In contrast, at an equivalent dose (100 nmol/kg), i.v. bolus injection of [F/G], HEX 1, and HEX 2 each produced a significant diuresis over the 80-min study (Fig. 2C; see Fig. 3 for time-course data for HEX 1). The peak increases in urine flow rate and urinary sodium produced by [F/G] and HEX 2 occurred 30 min after injection, whereas peak renal excretory responses to HEX 1 were evident by 40 min. The renal excretory responses produced by [F/G] and HEX 2 were fully recovered by 50 min (data not shown) after drug injection, whereas changes elicited by HEX 1 returned to control levels by 60 min (Fig. 3). Note that the changes in renal excretory function depicted in Fig. 2C do not reflect the potential maximum diuretic or antinatriuretic responses evoked by each NOP receptor partial agonist (i.e., as may be obtained from dose-response studies; Fig. 3) but simply illustrate that at an i.v. bolus dose of 100 nmol/kg or above (e.g., doses in which N/OFQ elicits marked cardiovascular depressor effects), these NOP receptor ligands elicited an entirely different profile of cardiovascular and renal responses than N/OFQ. Finally, in certain animals it was observed that immediately after i.v. injection each NOP receptor ligand produced a marked increase (spike and plateau) in renal sympathetic nerve activity, a response similar to that elicited by i.v. bolus N/OFQ but in opposition to the renal sympathoinhibitory response that occurred in other rats when the same drug was injected into the brain (data not shown).
Additional studies were performed to thoroughly investigate whether a high i.v. bolus dose of a purported NOP receptor partial agonist would elicit changes in cardiovascular or renal function similar to i.v. bolus N/OFQ. The results of these dose-response studies are shown in Fig. 3, which illustrates the time-course cardiovascular and renal responses produced by increasing i.v. bolus doses of HEX 1 in conscious Sprague-Dawley rats. Compared with each group control value, each i.v. bolus dose of HEX 1 (30, 100, 300, and 900 nmol/kg) produced significant changes in mean arterial pressure, urine flow rate, and urinary sodium excretion (for clarity, asterisks denoting statistically significant differences, P < 0.05, within each group versus each group's control value have been omitted). In particular, compared with respective group control values (C) the i.v. injection of HEX 1 at each doses tested produced a gradual but significant (P < 0.05) reduction in mean arterial pressure without altering heart rate. However, even at the highest dose tested (900 nmol/kg, i.v.) the pattern of the hypotensive response produced by HEX 1 (Fig. 3) was substantially different than the immediate but transient decrease in mean arterial pressure elicited by N/OFQ (30 or 100 nmol/kg; Figs. 2, A and B, and 4, A and B). Concurrent with the slight (30, 100, or 300 nmol/kg) or moderate (900 nmol/kg) hypotension, increasing i.v. bolus doses of HEX 1 also produced increases in urine flow rate and decreases in urinary sodium excretion (Fig. 3). HEX 1 produced a maximal diuretic response (50 min; Δ 151 ± 6 μl/min) at an i.v. bolus dose of 300 nmol/kg.
Figure 4, A and B, illustrate the changes in heart rate and mean arterial pressure produced by i.v. bolus N/OFQ in conscious rats pretreated i.v. with an NOP receptor partial agonist (same dose of NOP ligands as that used in studies depicted in Fig. 2, A–C). Values are peak changes (means ± S.E.) in mean arterial pressure and heart rate (from control predrug baseline values for each animal) produced by N/OFQ (30 nmol/kg, i.v.) in rats pretreated (5 min) with isotonic saline vehicle or [F/G] (900 nmol/kg, i.v.; Fig. 4A), or N/OFQ (100 nmol/kg, i.v.) in rats pretreated (5 min) with isotonic saline vehicle, HEX 1 (100 nmol/kg, i.v.; Fig. 4B) or HEX 2 (100 nmol/kg, i.v.; Fig. 4B). As shown, in isotonic saline vehicle-pretreated rats (which itself caused no changes), i.v. bolus N/OFQ (Fig. 4A, 30 nmol/kg; Fig. 4B, 100 nmol/kg) produced marked hypotension and bradycardia. The decreases in mean arterial pressure and heart rate produced by each i.v. bolus dose of N/OFQ were immediate in onset and persisted for approximately 5 to 10 min. In contrast to the N/OFQ-evoked responses, the i.v. bolus injection of [F/G] (Fig. 4A), HEX 1, or HEX 2 (Fig. 4B) did not significantly alter mean arterial pressure or heart rate over the same time period studied. Furthermore, in the same rats pretreated (5 min) i.v. with [F/G] (Fig. 4A), HEX 1, or HEX 2 (Fig. 4B), the characteristic and immediate hypotensive and bradycardic responses to an i.v. bolus N/OFQ challenge were either abolished ([F/G] and HEX 1) or attenuated (HEX 2). In other studies, it was observed that the hypotensive and bradycardia responses to i.v. bolus N/OFQ (100 nmol/kg) were not blocked by HEX 2 or [F/G] with a longer pretreatment time of 30 min (data not shown). However, after a 60-min pretreatment period, HEX 1 still blocked the cardiovascular depressor responses to i.v. N/OFQ.
At all the doses tested (Figs. 1, 2, 3, 4), the i.v. bolus injection of N/OFQ, [F/G], HEX 1, or HEX 2 did not produce any apparent behavioral/CNS (e.g., agitation, gnawing, licking, and exploratory) or sedative/catatonic effects over the course of the experimental protocol.
Discussion
The findings of these studies demonstrate that in conscious rats, NOP receptor partial agonists are functionally selective ligands that affect cardiovascular and renal function differently depending on the route of administration of the compound. When administered into the brain (i.c.v.), all NOP receptor ligands tested ([F/G], HEX 1, and HEX 2) behaved as full agonists, highly mimicking the effects of N/OFQ and producing marked cardiovascular (bradycardia and hypotension) and renal (diuresis, antinatriuresis, and renal sympathoinhibition) responses. In contrast, after peripheral (i.v. bolus) injection, these same NOP receptor ligands elicited a complex pharmacological and physiological profile that was different from that of N/OFQ and that ranged from full agonist (water diuresis), partial agonist (submaximal hypotension without altering heart rate) to antagonist (blockade of N/OFQ-evoked bradycardia and hypotension) behavior.
The compounds [F/G], HEX 1, and HEX 2 are recognized to behave functionally as NOP receptor partial agonists with varying degrees of efficacy in different biological model systems. However, there is now considerable evidence that each of these ligands can behave as pure antagonists (Guerrini et al., 1998; Bigoni et al., 1999; Madeddu et al., 1999, Berger et al., 2000; Malinowska et al., 2000b), partial agonists (Dooley et al., 1997; Bigoni et al., 1999; Berger et al., 2000; Calo' et al., 2000), or full agonists (Butour et al., 1998; Kapusta et al., 1999; Berger et al., 2000; Malinowska et al., 2000a; Olszewski et al., 2000) across different in vitro and in vivo systems (for review, see Calo' et al., 2000). The results of the present studies extend these observations and clearly demonstrate that these same NOP receptor ligands can display mixed pharmacological behavior from full/partial agonist to antagonist activity within a given biological system, in this case involving processes regulating cardiovascular and renal function in vivo.
As we reported previously for [F/G] (Kapusta et al., 1999), the i.c.v. injection of all three NOP receptor ligands in conscious rats produced cardiovascular depressor and water diuretic responses that were similar in pattern and magnitude to those elicited by N/OFQ, thus behaving as full agonists. Although not tested, it is likely that these NOP receptor ligands acted centrally to affect cardiovascular and renal function in a manner similar to N/OFQ through modulation of central neural (sympathetic inhibitory and parasympathetic stimulatory) outflow (Giuliani et al., 1997; Kapusta et al., 1999, 2002; Shirasaka et al., 1999) and inhibition of antidiuretic hormone release (Kakiya et al., 2000; Kapusta, 2000). In contrast to their responses in the brain, when [F/G], HEX 1, and HEX 2 were administered into the periphery as an i.v. bolus injection, these compounds did not alter heart rate and only gradually and slightly reduced mean arterial pressure. These observations are of interest considering that N/OFQ (30 or 100 nmol/kg) characteristically produces an immediate and marked bradycardia and hypotension after i.v. bolus injection in conscious or anesthetized rats (Champion et al., 1997; Champion and Kadowitz, 1997; Bigoni et al., 1999; Madeddu et al., 1999; Kapusta, 2000; Malinowska et al., 2000a, 2002). However, as partial agonists, it might be expected that these ligands are required to bind to and activate more receptors to elicit an equal response. This possibility was excluded though, since in dose-response studies even the highest dose of the NOP receptor partial agonist tested (HEX 1, 900 nmol/kg, i.v.) did not affect mean arterial pressure or heart rate in a manner similar to that elicited by i.v. bolus N/OFQ. Although the mechanism(s) by which N/OFQ and NOP receptor partial agonists produce different cardiovascular responses remains to be determined, it is possible that anesthesia may influence this pathway. This is suggested since, in urethane-anesthetized rats, [F/G] and HEX 1 produced a significant bradycardia and hypotension (Malinowska et al., 2000a).
In the current study, the i.v. bolus pretreatment (5 min) of rats with [F/G], HEX 1, and HEX 2 prevented/attenuated the hypotension and bradycardia typically evoked by an i.v. bolus N/OFQ challenge. These findings demonstrate that these NOP receptor ligands also display antagonist activity and can block the peripheral mechanisms by which N/OFQ affects heart rate and mean arterial pressure. Similarly, Madeddu et al. (1999) demonstrated that, in conscious mice, i.v. bolus [F/G] did not alter mean arterial pressure or heart rate but prevented the hypotension, bradycardia, and increase in aortic blood flow evoked by N/OFQ. Of interest, we demonstrated that at a time in which i.v. bolus pretreatment of rats with HEX 1 completely blocked the cardiovascular responses to i.v. bolus N/OFQ, the cardiovascular depressor responses to central (i.c.v.) injection of N/OFQ remained intact. Although it remains to be tested, this observation provides support for separate central versus peripheral NOP receptor systems that control cardiovascular function.
In contrast to their partial agonist (submaximal hypotension) and antagonist effects on cardiovascular function, when administered alone i.v. bolus [F/G], HEX 1, and HEX 2 produced significant diuretic and antinatriuretic responses (i.e., water diuresis). The renal responses to these ligands were unexpected and of merit considering that all i.v. bolus doses of N/OFQ (30, 100, or 300 nmol/kg) tested did not itself affect urine flow rate. Of interest though, in previous studies we showed that N/OFQ is effective in producing a water diuresis when administered as a continuous i.v. infusion (Kapusta et al., 1997; Kapusta, 2000). Moreover, during i.v. infusion N/OFQ (low or high dose) does not elicit any marked cardiovascular responses and instead produces only a subtle reduction in mean arterial pressure with no change in heart rate (Kapusta et al., 1997; Kapusta, 2000), these being cardiovascular responses similar to those elicited by i.v. bolus injection of NOP receptor partial agonists (present study). Although the mechanisms have yet to be explored, it is apparent that by altering the method of i.v. drug administration (infusion versus bolus injection) the pattern of cardiovascular and renal excretory responses produced by N/OFQ can change and can highly mimic that elicited by the i.v. bolus injection of the NOP receptor partial agonists.
At present, the mechanisms by which purported NOP receptor partial agonists produce functionally selective effects on cardiovascular and renal function remain unknown. Different subtypes of NOP receptors in central versus peripheral tissues have been speculated but not reported to exist. Alternatively, the NOP receptor density and stimulus/response coupling efficiency in various tissues (e.g., potentially high in the CNS and low in peripheral tissues) may influence the degree of agonism of the three low efficacy agonists (i.e., partial agonists) used in this study (Berger et al., 2000; McDonald et al., 2003). This premise is supported by studies that have used an ecdysone-inducible expression system showing that partial agonist behavior of a ligand is dependent upon the level of NOP receptor expression (McDonald et al., 2003). Together, our data strongly indicate that there exists agonist-specific regulation of the NOP receptor. Structure-activity studies have suggested that the mode of binding between the hexapeptide HEX 1 and the NOP receptor is different from that between N/OFQ and NOP receptors (Kawano et al., 2002). In fact, using photoaffinity labeling, Bes and Meunier (2003) have identified a hexapeptide binding site within the NOP receptor that is physically remote and distinct from the region in which N/OFQ binds. As suggested by these investigators, it is likely that the ability of the hexapeptides and N/OFQ to interact with the NOP receptor in different ways (i.e., effects on G protein coupling and second messenger pathways) is consistent with their distinct pharmacological activities. Of interest, Corbani et al. (2004) demonstrated that the full agonists N/OFQ and Ro64-6198 induced rapid internalization of the human NOP receptor, whereas antagonists and the partial agonist Ac-RYYRWR-NH2 had little effect on internalization. These findings are of merit in that N/OFQ failed to alter urine flow rate at any i.v. bolus dose tested. Based on the observations by Corbani et al. (2004), the initiation/onset of the renal excretory responses to NOP receptor partial agonists may be related to sustained ligand receptor binding/coupling and less potential to induce desensitization than full NOP receptor agonists such as N/OFQ. Instead, the duration of the renal excretory responses may be related to the dose and/or metabolic stability of the NOP receptor ligand (Kapusta et al., 2005). Finally, it remains to be determined whether different NOP receptor partial agonists undergo tissue-specific metabolism similar to N/OFQ (Terenius et al., 2000) and whether potential active fragments affect cardiovascular and renal function by NOP receptor-dependent or -independent pathways.
In summary, we demonstrated that in conscious rats NOP receptor partial agonists produced functionally selective effects on cardiovascular and renal function ranging from full agonist (i.c.v., cardiovascular depressor; i.c.v. and i.v., water diuresis), partial agonist (i.v., submaximal hypotension without altering heart rate) to antagonist (i.v., blockade of N/OFQ-evoked bradycardia and hypotension) behavior. Based on their ability to produce a selective water diuresis after i.v. bolus injection without apparent adverse cardiovascular or CNS effects, we propose that metabolically stable NOP receptor partial agonists (e.g., ZP120; Kapusta et al., 2005) may be useful therapeutically as novel peripherally acting aquaretics for the acute management of severe water retention and/or hyponatremia.
Footnotes
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This work was supported by National Institutes of Health, National Institute of Diabetes and Digestive and Kidney Diseases Grants DK-43337 and DK-02605; American Heart Association, Southeastern Affiliate 0255314B (to D.R.K.); and National Institutes of Health, Heart, Lung, and Blood Institute Grant HL71212 (to D.R.K. and G.C.). We note that funds made available to D.R.K. from the American Heart Association Grant 0255314B were entirely provided to the American Heart Association by a gracious donation from Herbert H. McElveen (DeRidder, LA).
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doi:10.1124/jpet.104.082768.
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ABBREVIATIONS: N/OFQ, nociceptin/orphanin FQ; NOP, nociceptin/orphanin FQ peptide; [F/G], [Phe1ψ(CH2-NH)Gly2]N/OFQ(1-13)-NH2; HEX 1, Ac-RYYRIK-NH2; HEX 2, Ac-RYYRWK-NH2; PE, polyethylene; HR, heart rate; bmp, beats per minute; MAP, mean arterial pressure; V, urine flow rate; UNaV, urinary sodium excretion; CNS, central nervous system; ZP120, Ac-RYYRWKKKKKKK-NH2; Ro64-6198, (1S,3aS)-8-(2,3,3a,4,5,6-hexahydro-1H-1-phenalen-1-yl)-1-phenyl-1,3,8-triazaspiro[4.5]decan-4-one.
- Received January 10, 2005.
- Accepted April 18, 2005.
- The American Society for Pharmacology and Experimental Therapeutics