Peripheral Injection of a New Corticotropin-Releasing Factor (CRF) Antagonist, Astressin, Blocks Peripheral CRF- and Abdominal Surgery-Induced Delayed Gastric Emptying in Rats

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Vol. 290, Issue 2, 629-634, August 1999

Peripheral Injection of a New Corticotropin-Releasing Factor (CRF) Antagonist, Astressin, Blocks Peripheral CRF- and Abdominal Surgery-Induced Delayed Gastric Emptying in Rats¹

Vicente Martínez², Jean Rivier and Y. Taché

CURE: Digestive Diseases Research Center, West Los Angeles Veterans Administration Medical Center, Department of Medicine, Digestive Disease Division, and Brain Research Institute, University of California at Los Angeles School of Medicine, Los Angeles, California; and The Clayton Foundation Laboratories for Peptide Biology, The Salk Institute for Biological Studies, La Jolla, California (J.R.)

	Abstract

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The effect of the corticotropin-releasing factor (CRF) receptor antagonists astressin and D-Phe CRF_12-41 injected i.v.on CRF-induced delayed gastric emptying (GE) was investigatedin conscious rats. Gastric transit was assessed by the recoveryof methyl cellulose/phenol red solution 20 min after its intragastricadministration. The 55% inhibition of GE induced by CRF (0.6 µgi.v.) was antagonized by 87 and 100% by i.v. astressin at 3 and10 µg, respectively, and by 68 and 64% by i.v. D-Phe CRF_12-41at 10 and 20 µg, respectively. CRF (0.6 µg)-injected intracisternally(i.c.) induced 68% reduction of GE was not modified by i.v. astressin(10 µg) whereas i.c. astressin (3 or 10 µg) blocked by 58 and100%, respectively, i.v. CRF inhibitory action. Abdominal surgerywith cecal manipulation reduced GE to 7.1 ± 3.1 and 27.5 ± 3.3%at 30 and 180 min postsurgery, respectively, compared with 40.3± 4.3 and 59.5 ± 2.9% at similar times after anesthesia alone.Astressin (3 µg i.v.) completely and D-Phe CRF_12-41 (20µg i.v.) partially (60%) blocked surgery-induced gastric stasisobserved at 30 or 180 min. The CRF antagonists alone (i.v. ori.c.) had no effect on basal GE. These data indicate that CRFacts in the brain and periphery to inhibit GE through receptor-mediatedinteraction and that peripheral CRF is involved in acute postoperativegastric ileus; astressin is a potent peripheral antagonist ofCRF when injected i.v. whereas i.c. doses $>=$ 3 µg exert dual centraland peripheral blockade of CRF action on gastrictransit.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Corticotropin-releasing factor (CRF) in the brain plays an important role in the behavioral, neuroendocrine, autonomic, immunologic,and visceral responses to stress (Irwin et al., 1990; Heinrichset al., 1995). In particular, central CRF is involved in stress-relatedalterations of gastrointestinal (GI) motor function (Taché etal., 1993; Martinez et al., 1997). It is also becoming increasingapparent that CRF administered peripherally can induce a similarpattern of GI responses in rats, mice, dogs, and humans as wheninjected centrally in rats or dogs (Pappas et al., 1985; Sheldonet al., 1990; Taché et al., 1993; Fukudo et al., 1998). Namely,CRF injected peripherally at similar dose ranges effective intothe cerebrospinal fluid (CSF) inhibits gastric contractility andemptying and slows small intestine transit while stimulating colonicmotility, transit, and fecal pellet output in rats and mice (Williamset al., 1987; Lenz et al., 1988a,b; Sheldon et al., 1990; Guéet al., 1991; Martinez et al., 1997). However, less is known aboutthe mechanism of action and role of peripheral, compared withcentral, CRF in visceral function (Taché et al., 1993).

CRF exerts its biological effects by binding to specific cell surface receptors on target tissues. CRF receptors are partof a subfamily of seven transmembrane domain receptors that arecoupled to adenylate cyclase via a guanine nucleotide stimulatoryfactor-signaling protein (Turnbull and Rivier, 1997). The CRFreceptor subtypes 1 (CRF-R1) and 2 (CRF-R2) have been cloned andshown to be encoded by two distinct genes (Dieterich et al., 1997).CRF-R2 exists in multiple forms as splice variants differing intheir amino terminus domains and distributions (Dieterich et al.,1997). CRF-R2 $alpha$ is found in the brain whereas CRF-R2 $beta$ is locatedin non-neuronal brain cells and the periphery, including the GItract in rats and humans (Dieterich et al., 1997). The predominantreceptor subtype in the pituitary gland is CRF-R1 (Chalmers etal., 1995), consistent with pharmacologic and binding studiesshowing that the peripheral action of CRF to stimulate pituitaryadrenocorticotropin (ACTH) release is mediated primarily by CRF-R1and the recent use of CRF-R1 knockout mice (Turnbull and Rivier,1997; Smith et al., 1998; Timpl et al., 1998). Indirect pharmacologicevidence suggests that CRF-R2 mediates peripheral CRF-inducedrelaxation of mesenteric small arteries (Rohde et al., 1996) anddelayed gastric emptying (GE; Nozu et al., 1999), although thisneeds to be ascertained further using selective CRF receptor subtypeantagonists.

Three generations of CRF analogs with specific competitive antagonist activity to the CRF receptors have been developed including $alpha$ -helical CRF_9-41, the first reported CRF antagonist (Rivieret al., 1984), followed by D-Phe CRF_12-41 and, more recently,the constrained astressin and its analogs (Hernandez et al., 1993;Gulyas et al., 1995; Miranda et al., 1997; Rivier et al., 1998). $alpha$ -Helical CRF_9-41 blocked various central and peripheralbiological actions of CRF while lacking potency to antagonizeCRF-induced pituitary ACTH release, suggesting that this CRF analogpreferentially is a CRF-R2 antagonism (Fisher et al., 1991; Kishimotoet al., 1995; Rivier et al., 1996; Turnbull et al., 1996). Bycontrast, D-Phe CRF_12-41 and astressin display high affinityto both CRF-R1 and CRF-R2 $alpha$ / $beta$ in vitro and prevent ACTH releaseinduced by i.v. CRF in rats (Gulyas et al., 1995; Perrin et al.,1995; Rivier et al., 1996).

To date, the influence of peripheral administration of CRF antagonists on systemic injection of CRF- or stress-induced alterationsof GI motor function has received little attention, and most ofthe information is derived from the influence of $alpha$ -helical CRF_9-41tested at one dose (Williams et al., 1987; Barquist et al., 1992;Hernandez et al., 1993). Abdominal surgery-induced acute postoperativegastric ileus was prevented partly by i.v. injection of $alpha$ -helicalCRF_9-41 at a similar dose, which fully reverses i.v. CRFin rats (Barquist et al., 1992; Hernandez et al., 1993). Williamset al. (1987) also showed that $alpha$ -helical CRF_9-41 injectedat a similar dose either i.c.v. or i.v. prevented restraint-inducedstimulation of colonic transit. These findings indicate that peripheraladministration of CRF antagonist also counteracts stress-relatedalterations of GI motorfunction.

To assess further the role of peripheral CRF in the delayed GE induced by surgical stress in rats, we first investigated theantagonist activity of i.v. injection of the constrained CRF analog,astressin, compared with D-Phe CRF_12-41 (Gulyas et al.,1995) on i.v. CRF-induced delayed gastric transit. Second, inview of growing evidence of exchanges of peptides across the blood-brainbarrier, including transport of CRF from the brain into the circulation(Banks and Kastin, 1996; Martins et al., 1997) and the aforementionedsimilar potency of $alpha$ -helical CRF_9-41 given centrally orperipherally, we tested whether astressin injected i.v. influencesi.c. CRF-induced delay in GE (Taché et al., 1993) and, conversely,whether astressin injected into the cisterna magna antagonizesi.v. CRF action. Last, we assessed the influence of peripheralinjection of astressin and D-Phe CRF_12-41 on abdominal surgery-inducedacute postoperative gastricileus.

	Materials and Methods

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Animals

Adult male Sprague-Dawley rats (Harlan, San Diego, CA) weighing 250 to 280 g were housed in group cages with free access tofood (Purina Rat Chow) and tap water. Animals were maintainedat a 12-h light/dark cycle and under controlled temperatures (21-23°C).Rats were fasted, but had free access to water for 18 to 20 hbefore experiments, which were conducted under the Veteran AdministrationAnimal Component of Research Protocol number 96-080-08.

Peptides and Injections

Rat/human CRF (r/hCRF), astressin [cyclo(30-33) [D-Phe¹²,Nle^21,38,Glu³⁰,Lys³³]r/hCRF_12-41], and D-Phe CRF_12-41, [D-Phe¹²,Nle^21,38,CMeLeu³⁷]r/hCRF_12-4 were synthesized by using the solid-phase approachand the Boc strategy and purified as described previously (Gulyaset al., 1995; Rivier et al., 1998). Peptides were stored in powderform at $-$ 70°C, and immediately before the experiments CRF wasdissolved in sterile saline, and astressin and D-Phe CRF_12-41were dissolved in double-distilled water (pH 7.0, warmed to 37°C).

Intravenous injections were performed under short enflurane anesthesia (3-5 min, 5.5% vapor concentration in O₂; Ethrane-Anaquest,Madison, WI) by delivering vehicle and peptides in 0.1 ml throughthe right jugular vein. Intracisternal (i.c.) injections wereperformed acutely under short enflurane anesthesia (2-3 min) bypuncture of the occipital membrane with a 50-µl Hamilton syringein rats placed in a stereotaxic equipment. Presence of CSF intothe Hamilton syringe upon aspiration before injection ensuredcorrectness of needle placement in the cisternamagna.

Measurement of GE

GE of a non-nutrient viscous meal was determined by the phenol red method as described previously (Maeda-Hagiwara and Taché,1987). The noncaloric liquid meal consisted of a viscous suspensionof continuously stirred 1.5% methyl cellulose (w/v; Sigma ChemicalCo., St. Louis, MO) containing phenol red (50 mg/100 ml; Sigma)given intragastrically (1.5 ml) to conscious rats. Twenty minutesafter administration of the meal, rats were euthanized by CO₂inhalation. The abdominal cavity was opened, the gastroesophagealjunction and the pylorus were clamped, and the stomach was isolatedand rinsed in 0.9% saline. After removing the clamps, the stomachwas placed in 100 ml of 0.1 N NaOH and homogenized (Polytron;Brinkman Instruments, Inc., Westbury, NY). The suspension wasallowed to settle for 1 h at room temperature, and then 5 ml ofthe supernatant was added to 0.5 ml of 20% trichloroacetic acid(w/v; Sigma) and then centrifuged at 3000 rpm at 4°C for 20 min.The supernatant was mixed with 4 ml of 0.5 N NaOH, and the absorbanceof the sample was read at 560 nm (Shimazu 260 Spectrophotometer).Phenol red recovered from animals euthanized immediately afterthe administration of the liquid meal was used as a standard (0%emptying). Percent emptying in the 20-min period was calculatedaccording to the following equation: % emptying = (1 $-$ absorbanceof test sample/absorbance of standard) ×100.

Experimental Procedures

In each daily experiment, a vehicle and 2 to 3 doses of each test substance were included and repeated on multiple days ondifferent animals. The i.c. and i.v. doses of CRF were selectedbased on previous dose-response studies showing a 50 to 70% inhibitionof GE in doses ranging from 0.3 to 0.6 µg/rat (Taché et al.,1987; Martinez et al., 1997). Doses of astressin were selectedbased on previous i.c. dose-related antagonism of i.c. CRF (Martinezet al., 1997). After the i.v. injections, animals were returnedto their home cages and, 10 min later, except otherwise mentioned,the noncaloric viscous meal was administered per oral intubationto awake rats, and the content of the stomach was assessed 20min later to calculate GE.

Influence of i.v. CRF Antagonists on i.v. CRF-Induced Inhibition of GE. Under short enflurane anesthesia, either astressin (1, 3, or 10 µg), D-Phe CRF_12-41 (1, 3, 10, or 20 µg), or water (0.1ml) was injected i.v. immediately before the i.v. injection ofeither CRF (0.6 µg) or saline (0.1 ml) in fastedrats.

Influence of i.v. CRF Antagonists on i.c. CRF-Induced Inhibition of GE. Under enflurane anesthesia, astressin (10 µg), D-Phe CRF_12-41 (20 µg), or water (0.1 ml) was injected i.v. immediatelybefore the i.c. injection of CRF (0.6 µg) or saline (10 µl).

Influence of i.c. Astressin on i.v. CRF-Induced Inhibition of GE. Under short enflurane anesthesia, astressin (1, 3, or 10 µg) or water (10 µl) was administered i.c. immediately before thei.v. injection of either CRF (0.6 µg) or saline (0.1ml).

Influence of i.v. CRF Antagonists on Abdominal Surgery-Induced Inhibition of GE. In rats exposed to enflurane anesthesia for 10 min, either water (0.1 ml), astressin (1, 3, or 10 µg), or D-Phe CRF_12-41(1, 3, 10, or 20 µg) was injected i.v. and abdominal surgery withcecal manipulation was performed as described previously (Martinezet al., 1997). Abdominal surgery consisted of a medial celiotomy(3-4 cm) and exteriorization of the cecum, which was handled ingauze soaked with saline for a 1-min period. The cecum then wasreturned to the abdominal cavity. The linea alba and the skinwere sutured separately with 3-0 silk suture. The noncaloric mealwas administered intragastrically at 10 or 160 min after removalof the anesthetic, and GE was monitored 20 minlater.

Statistical Analysis

Results are expressed as mean ± S.E. Comparisons within groups were performed using ANOVA followed by a Student-Newman-Keulsmultiple-comparison test. P values < .05 were considered statisticallysignificant.

	Results

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Influence of i.v. Astressin and D-Phe CRF_12-41 on i.v. CRF-Induced Inhibition of GE. In the control group (n = 11), rats injected i.v. with water plus saline (0.1 ml each), 55.7 ± 3.3% of the noncaloric viscousmeal was emptied in 20 min. The i.v. injections of water followedby CRF (0.6 µg) reduced GE to 24.9 ± 2.9% (n = 11) (P < .05 versuscontrol; ANOVA: F_6,43 = 8.211) (Fig. 1). Astressin (1, 3, and10 µg) injected i.v. immediately before that of CRF (0.6 µg) dose-dependentlyprevented CRF inhibitory action (Fig. 1). A partial blockade ofi.v. CRF was induced by astressin at 1 µg, as shown by the increasein GE to 41.2 ± 8.8% (n = 6, P < .05 versus i.v. water + CRF),whereas at higher doses (3 or 10 µg) astressin completely antagonizedthe CRF inhibitory effect (GE: 51.6 ± 3.2%, n = 6, and 58.4 ±5.6%, n = 8, respectively, P < .01 versus water + CRF; P > .05versus water + saline). Astressin alone (3 or 10 µg i.v.) didnot modify basal GE (51.0 ± 3.8 and 54.7 ± 7.8%, respectively,n = 4 for each dose). D-Phe CRF_12-41 injected i.v. at 1or 3 µg did not modify i.v. CRF-induced inhibition of GE (23.1± 2.1%, n = 3, and 24.6 ± 1.3%, n = 5, respectively; Fig. 1) whereasat 10 and 20 µg, GE was increased similarly to 45.7 ± 3.3 and44.5 ± 1.1% (n = 5; for each group, P < .01 versus vehicle + CRF;P > .05 versus water + saline; F_5,26 = 12.859; Fig. 1). D-PheCRF_12-41 (20 µg i.v.) alone did not influence the basalGE (53.0 ± 7.8%, n = 4; P > .05 versus water + saline).

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Fig. 1. Intravenous injection of the CRF antagonists D-Phe CRF_12-41 and astressin dose-dependently reversed the inhibition of GE induced by i.v. CRF in conscious rats. Rats under short enflurane anesthesia were injected i.v. either with water, D-Phe CRF_12-41, or astressin and, immediately after, with i.v. saline or CRF. A noncaloric viscous meal was administered 10 min after the last i.v. injection, and GE was monitored 20 min after. Data represent the mean ± S.E. of 3 to 11 animals per dose. *P < .05 versus the water + CRF (CRF antagonist dose of 0); ⁺P < .05 versus i.v. D-Phe CRF_{12-4 1} + i.v. CRF, at the same dose; ^#P < .05 versus i.v. water + i.v. saline; broken line: 55.7 ± 3.3%.

Influence of i.v. CRF Antagonists on i.c. CRF-Induced Inhibition of GE. In control rats injected i.v. with water followed by i.c. injection of saline (n = 4), 53.0 ± 4.7% of the non-nutrient mealwas emptied 20 min after its administration. The i.c. injectionof CRF (0.6 µg) immediately after the i.v. injection of waterdecreased GE to 17.1 ± 4.1% (n = 4) (P < .001 versus control;F_3,13 = 24.612) (Fig. 2). Astressin injected i.v. (10 µg) didnot modify i.c. CRF-induced inhibition of emptying (20.7 ± 4.5%,n = 5; P > .05 versus i.v. water + i.c. CRF; Fig. 2). D-Phe CRF_12-41(20 µg i.v.) also did not affect i.c. CRF (0.6 µg)-induced inhibitionof GE [i.v. D-Phe CRF_12-41 + i.c. vehicle: 52.3 ± 6.2%,n = 3; i.v. vehicle + i.c. CRF: 22.4 ± 5.3%, n = 2; i.v. D-PheCRF_12-41 + i.c. CRF: 30.0 ± 1.0%, n = 4; F_2,6 = 13.351,P = .006].

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Fig. 2. Effect of i.c. and i.v. injection of astressin on CRF-induced inhibition of GE in conscious rats. Rats, under enflurane anesthesia, were injected i.c. with water or astressin followed by the i.v. injection of saline or CRF. In a separate experiment, water or the highest effective dose of astressin blocking i.v. CRF inhibitory effect was injected i.v. immediately before the i.c. injection of either saline or CRF. The GE of a noncaloric viscous meal was determined during the 10- to 30-min period after peptide administration. Each column represents the mean ± S.E. of the number of animals shown at the top. *P < .05 versus vehicle controls; ^#P < .05 versus i.c. saline + i.v. CRF.

Influence of i.c. Astressin on i.v. CRF-Induced Inhibition of GE. The i.c. injection of water (10 µl) immediately followed by the i.v. injection of CRF (0.6 µg) reduced gastric transit ofthe non-nutrient meal to 13.6 ± 4.4% (n = 6) compared with 47.1± 4.4% (n = 5) in i.c. water plus i.v. saline-treated animals(P < .01; F_6,26 = 9.552; Fig. 2). Astressin (1, 3, and 10 µg)injected i.c. dose-dependently inhibited i.v. CRF-induced delayedGE. The lower i.c. dose of astressin did not modify i.v. CRF inhibitoryaction on GE (13.0 ± 4.6%, n = 4; P > .05 versus i.c. water +i.v. CRF) whereas i.c. astressin at 3 and 10 µg resulted in apartial (32.9 ± 10.0%, n = 5) and complete (52.8 ± 3.5%, n = 5)normalization of GE values in i.v. CRF-injected rats (Fig. 2).

Influence of i.v. Astressin and D-Phe CRF_12-41 on Abdominal Surgery-Induced Inhibition of GE. In animals maintained for 10 min under enflurane anesthesia and injected i.v. with water, the GE of the non-nutrient mealreached 40.3 ± 4.3% (n = 5) during the 10- to 30-min period postanesthesia(Fig. 3). Abdominal surgery (laparotomy and 1-min cecal manipulation)performed under 10 min of enflurane anesthesia reduced gastrictransit to 7.1 ± 3.1% (n = 5) as determined during the 10- to30-min period after anesthesia plus surgery (Fig. 3). Astressin(1, 3, and 10 µg i.v.) injected before the surgery dose-dependentlyreversed the inhibitory effect of abdominal surgery (GE valueswere 21.7 ± 1.9, 34.8 ± 4.2, and 30.2 ± 2.9%, respectively; n= 4 to 5 per group, P < .05 versus water + surgery; Fig. 3).

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Fig. 3. Intravenous injection of the CRF antagonist astressin dose-dependently blocked the inhibition of GE observed at 30 min after laparotomy and 1-min cecal manipulation in conscious rats. Rats, under enflurane anesthesia for 10 min, were injected i.v. either with water or astressin immediately before the surgical procedure. The GE was determined during the 10- to 30-min period after surgery. Each column represents the mean ± S.E. of the number of rats shown at the top. *P < .05 versus all other experimental groups (ANOVA: F_6,25 = 7.24, P < .0001). ^#P < .05 versus water + abdominal surgery.

In rats maintained under enflurane anesthesia during 10 min and injected i.v. with water, the GE assessed during the 160-to 180-min period postanesthesia was 59.5 ± 2.9% (n = 10) in rats.Abdominal surgery (laparotomy and 1-min cecal manipulation) performedunder similar duration of anesthesia reduced gastric transit to27.5 ± 3.3% as assessed during the 160- to 180-min period anesthesiaplus postsurgery [n = 11, P < .01 versus enflurane alone or astressinalone; ANOVA: F_6,35 = 13.019, P < .001; Fig. 4]. Astressin injectedi.v. at 1 µg partially prevented and, at 3 and 10 µg, completelynormalized abdominal surgery-induced delayed gastric transit (GEvalues were 44.1 ± 5.4%, n = 5; 58.0 ± 1.2%, n = 5; and 54.1 ±4.6%, n = 4, respectively, P < .001 versus water + surgery; Fig.4). D-Phe CRF_12-41 (1 or 3 µg i.v.) did not modify abdominalsurgery-induced inhibition of GE (19.8 ± 4.3%, n = 3, and 24.3± 1.1%, n = 5, respectively). Whereas at 10 and 20 µg, the CRFantagonist partially suppressed the inhibitory effect of surgery,GE values were increased to 47.6 ± 2.0 and 46.7 ± 1.7%, respectively(n = 4 for each dose; P < .01 versus water + surgery; P < .05versus i.v. water + anesthesia; Fig. 4). Astressin (12 or 40 µgi.v.) or D-Phe CRF_12-41 (20 µg i.v.) alone did not influencesignificantly basal GE monitored during the 160- to 180-min periodafter i.v. injection (58.1 ± 3.7%, n = 4, and 53.2 ± 8.0% and47.1 ± 2.4%, n = 3, respectively; P > .05 versus i.v. water).

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Fig. 4. Intravenous injection of the CRF antagonists D-Phe CRF_12-41 and astressin dose-dependently reversed the inhibition of GE observed 180 min after laparotomy and 1-min cecal manipulation in conscious rats. Rats, under enflurane anesthesia for 10 min, were injected i.v. either with water, astressin, or D-Phe CRF_12-41 immediately before the surgical procedure. The GE was determined during the 160- to 180-min period after surgery. Data represent mean ± S.E. of 3 to 11 animals per dose. *P < .05 versus i.v. water + surgery group (CRF antagonist dose of 0); ⁺P < .05 versus i.v. D-Phe CRF_12-41; ^#P < .05 versus the i.v. water + anesthesia alone (broken line: 59.5 ± 2.9%).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

CRF injected i.v. inhibited GE of a noncaloric meal as reported previously using peripheral (i.v., i.p., or s.c.) administrationin rats, mice, or dogs (Pappas et al., 1985; Williams et al.,1987; Lenz et al., 1988a,b; Broccardo and Improta, 1990; Raybouldet al., 1990; Barquist et al., 1992). Astressin injected i.v.at 1, 3, and 10 µg antagonized CRF action by 53, 87, and 100%,respectively, whereas D-Phe CRF_12-41 at 10 or 20 µg partiallyreversed CRF, and lower doses had no effect. Previously, i.v. $alpha$ -helical CRF_9-41 at 50 µg completely blocked i.v. CRF-induceddelay GE under the same conditions (Barquist et al., 1992). Thesefindings show a greater efficacy of astressin to block the biologicalaction of systemic injection of CRF on visceral function. In vivo,the antagonist action of astressin and D-Phe CRF_12-41 injectedperipherally has been explored only in regard to the blockadeof CRF-dependent increase in pituitary ACTH release in which astressinwas found to be >10-fold more potent than any other CRF receptorantagonists (Hernandez et al., 1993; Gulyas et al., 1995; Rivieret al., 1996; Turnbull and Rivier, 1997; Perrin et al., 1999).

CRF injected i.c. or i.v. in vehicle-treated rats resulted in a similar 68 to 71% inhibition of GE. These results corroborateprevious reports showing that CRF inhibits gastric transit witha similar potency when delivered into the circulation or the CSFin rats (Taché et al., 1987; Williams et al., 1987). Althoughan exchange of peptides across the blood-brain barrier exists(Banks and Kastin, 1996), the absence of transport of CRF fromthe peripheral circulation into the brain has been established(Martins et al., 1996, 1997). In addition, astressin injectedi.v. at a dose that completely blocked the action of CRF injectedi.v. did not influence i.c. CRF-induced gastric stasis. Therefore,circulating astressin does not seem to enter the brain after i.v.administration and would not be able to antagonize a direct centralaction of CRF at the doses tested. Taken together, these resultsindicate that the inhibition of GE induced by i.c. injection ofCRF at 0.6 µg is centrally mediated and not related to a peripheralaction after leakage into the circulation. Likewise, CRF antibodyor $alpha$ -helical CRF_9-41 injected peripherally, at doses blockingperipherally administered CRF-induced delayed gastric transit,did not influence the inhibitory action of CRF injected into theCSF in rats or mice (Taché et al., 1987; Lenz et al., 1988b;Sheldon et al., 1990; Riviere et al., 1994).

By contrast, astressin injected i.c. at 3 and 10 µg was able to block i.v. CRF-induced inhibition of GE by 58 and 100%, respectively,whereas at 1 µg, it had no effect. We reported previously thatastressin injected i.c. at 1, 3, and 10 µg antagonized by 33,100, and 100% i.c. CRF-induced inhibition of GE tested under thesame conditions (Martinez et al., 1997). The mechanisms throughwhich i.c. injected astressin antagonizes peripheral CRF remainto be elucidated in relation to active transport and/or leakagefrom the brain to the periphery as established for CRF or otherpeptides (Banks and Kastin, 1996; Martins et al., 1997). Irrespectiveof the mechanism, these data indicate that astressin injectedi.c. can antagonize CRF action on gastric motor function at bothcentral and peripheral sites, particularly when i.c. doses $>=$ 3µg of peptide areused.

In experimental animals and humans, surgical stress is known to induce gastric stasis (Taché et al., 1991; Resnick et al.,1997) and to increase CRF release in the brain and the circulation(Giuffre et al., 1988; Naito et al., 1991; Bonaz and Taché, 1994).Abdominal surgery and cecal manipulation inhibited GE by 82 and53% compared with anesthesia alone at 30 and 180 min, respectively,after the end of surgery, in agreement with our previous reportsin rats (Taché et al., 1991; Barquist et al., 1992, 1996; Martinezet al., 1997). Astressin injected i.v. at a low dose (3 µg) completelyblocked abdominal surgery-induced delayed GE either at 30 or 180min. The use of i.v. astressin shows that peripheral CRF receptorsplay a primary role in the postoperative gastric ileus. By contrast,D-Phe CRF_12-41 injected i.v. at 3.3- or 6.6-fold-higherdoses than astressin resulted in partial (63-60%) blockade. Ina previous study, we showed that $alpha$ -helical CRF_9-41 injectedi.v. at 50 µg also result in a 60% inhibition of postoperativeileus under the same conditions (Barquist et al., 1992). Thesedata indicate that astressin is a more potent antagonist of bothendogenous and exogenous CRF action on gastric motor functionthan previously developed CRF receptor antagonists. The high potencyof astressin, compared with that of the previous generation ofCRF antagonists, may be related to its very low intrinsic activityand/or binding affinity to the CRF-binding protein; metabolicstability leads to an increased duration of action (Gulyas etal., 1995; Miranda et al., 1997; Perrin et al., 1999). The antagonisticeffect of astressin injected i.v. was assessed previously mainlyin relation with endogenous CRF-dependent stimulation of ACTHrelease induced by adrenalectomy, electroshock, ethanol, or lipopolysaccharide,although higher i.v. doses were required to exert a antagonistaction over a 90-min period (Gulyas et al., 1995; Rivier et al.,1996; Aubry et al., 1997).

Astressin injected into the cisterna magna at a dose range similar to that injected i.v. in the present study also revertedabdominal surgery-induced gastric ileus assessed after 180 min(Martinez et al., 1997). These results indicate that CRF receptoractivation is involved at both peripheral and central sites toinduce postoperative gastric ileus. However, whether the completeprevention of postoperative gastric ileus induced by astressininjected i.c. at 3 and 10 µg (Martinez et al., 1997) results solelyfrom a central action is difficult to ascertain based on the presentdemonstration that at such i.c. doses, astressin antagonized peripheralCRF as well. The delayed GE induced by stressors of immunological(i.v. interleukin 1 $beta$ ; Sütö et al., 1996), psychological (partialrestraint; Williams et al., 1987; Lenz et al., 1988b), physical(swim; Co $s$ kun et al., 1997), chemical (ether; Taché et al.,1991), or nociceptive (i.p. injection of acetic acid; Riviereet al., 1994) nature was prevented by CSF, unlike peripheral injectionof $alpha$ -helical CRF_9-41 in rats (Williams et al., 1987; Lenzet al., 1988b; Riviere et al., 1994; Sütö et al., 1996). Whetherperipheral CRF receptors are selectively recruited by abdominalsurgery/visceral manipulation compared with other stressors needsto be furtherassessed.

In summary, the newly developed CRF antagonist, astressin, injected i.v. blocked i.v. CRF-induced inhibition of GE at a low(3:0.6 µg/rat) antagonist/agonist dose ratio and displayed higherpotency than D-Phe CRF_12-41 in conscious rats. The lackof reversal of i.c. CRF-induced delay GE by i.v. astressin indicatesthat i.c. CRF inhibitory action is centrally mediated and thati.v. astressin antagonist action is exerted at the periphery.By contrast, astressin injected i.c. exerts a dual central andperipheral CRF antagonist action that needs to be taken into considerationwhen i.c. doses $>=$ 3 µg of astressin are used. In addition, theblockade of abdominal surgery-induced delayed GE by i.v. astressinindicates that peripheral CRF receptors play an important rolein acute postoperative gastric ileus. Taken together, these datashow that astressin is a valuable new tool to assess the roleof peripheral CRF in the GI motor response to somatovisceralstress.

	Acknowledgments

We thank Paul Kirsch for his help in the preparation of themanuscript.

	Footnotes

Accepted for publication March 9, 1999.

Received for publication November 20, 1998.

¹ This work was supported by the National Institute of Diabetes and Digestive and Kidney Diseases, Grants DK-33061 (Y.T.), DK-26741(J.R.), and DK-41301 (Animal Core, Y.T.).

² Present address: Centro de Estudíos Universitarios San Pablo, Veterinary School, Department of Physiology, 46113 Moncada,Valencia,Spain.

Send reprint requests to: Dr. Yvette Taché, Ph.D., Building 115, Room 203, West Los Angeles Veterans Administration Medical Center, 11301 Wilshire Blvd., Los Angeles, CA 90073. E-mail: ytaché{at}ucla.edu

	Abbreviations

CRF, corticotropin-releasing factor; CRF-R1 and CRF-R2, corticotrophin-releasing factor receptor subtypes 1 and 2, respectively; CSF, cerebrospinal fluid; D-Phe CRF_12-41, [D-Phe¹²,Nle^21,38,CMeLeu³⁷]r/h CRF_12-41; i.c., intracisternal; GE, gastric emptying; GI, gastrointestinal; ACTH, adrenocorticotropin; r/hCRF, rat/human CRF.

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