Jennifer E. Shook

II. Regulation of gastrointestinal function by multiple opioid receptors

Agonist and antagonist drugs possessing selectivity for individual types of opioid receptors have been employed in vitro and in vivo to determine the mechanisms by which opioids regulate gastrointestinal functions. Selective mu opioid agonists given by intracerebroventricular (i.c.v.) injection, by intrathecal (i.t.) injection, or by peripheral (s.c. or i.v.) injection in rats or mice decreased gastrointestinal transit and motility, inhibited gastric secretion, and suppressed experimentally-induced diarrhea. Selective delta agonists, by contrast, inhibited gastrointestinal transit after i.t., but not after i.c.v. or s.c. administration. Delta agonists also did not alter gastric secretion after i.c.v. or s.c. injection. However, delta agonists exhibited antidiarrheal effects after i.c.v., i.t., or s.c. administration. Kappa agonists given i.c.v. had no effect on gastrointestinal transit in rats or mice or on gastric secretion in rats, but exhibited antidiarrheal effects in mice. The kappa agonist U-50, 488H given peripherally increased gastric acid secretion. Different types of opioid receptors in different anatomical sites influence differently gastrointestinal motility and propulsion, gastric secretion, and mucosal transport. Brain, spinal cord, enteric neural and smooth muscle opioid receptors represent chemosensitive sites for regulation of gastrointestinal function.

A novel bioassay for the NK-2 neurokinin receptor: The guinea pig gallbladder

Although three neurokinin receptors (NK-1, NK-2, NK-3) have been identified by radioligand binding assays, only the NK-1 and NK-3 types have been found in smooth muscle bioassays. In this study, evidence is presented demonstrating functional NK-2 type receptors in the guinea pig gallbladder (GPGB). The potencies of the following neurokinins were determined in the GPGB and the guinea pig ileum (GPI): substance P (SP), physalaemin (PH), eledoisin (EL), substance K (SK) and kassinin (KA). ED50 values were determined by linear regression analysis of the dose-related increases in the force generated by each peptide. In the GPI, the rank order of potency was SP = PH = EL greater than SK = KA, indicating NK-1 selectivity. In the GPGB, the relative potencies were SK greater than KA greater than EL much greater than PH greater than SP, which is similar to that reported for the NK-2 receptor in radioligand binding assays. These findings demonstrate the NK-2 receptor tissue selectivity of the GPGB.

Spinally mediated opioid antidiarrheal effects

To assess the role of opioid receptors in the spinal cord in regulation of functions of the intestinal mucosa in a secretory model, we evaluated the ability of i.t. administered mu (PL017), delta (DPDPE) and kappa (U50,488H) selective opioid agonists to inhibit diarrhea produced in mice by an injection of prostaglandin E2 (PGE2) (200 micrograms/mouse, i.p.). I.t. PL017 and DPDPE inhibited diarrhea in a dose-related fashion. U50,488H had only minimal antidiarrheal effects. The i.t. doses of PL017 and DPDPE required to inhibit diarrhea were higher than the doses required to produce antinociception and inhibit gastrointestinal transit. Spinally administered PL017 and DPDPE were considerably less potent in the diarrhea model than after i.c.v. administration but far more effective than after peripheral (s.c.) dosing. The antidiarrheal effects of spinally administered opioids were antagonized by concurrently administered naloxone. These data indicate that opioid chemosensitive sites in the spinal cord can modulate diarrhea produced by PGE2, and that the receptor specific opioids, PL017 and DPDPE, and to a lesser extent U50,488H, all possess antidiarrheal activity when administered i.t.

Synthesis and biological evaluation of Nα-hydroxysulfonyl-[Nle28,31]-CCK26–33

Abstract Two analogues of [Nle 28,31 ]-CCK 26–33 containing an N-terminal acetyl or N-terminal hydroxysulfonyl moiety were prepared and characterized. Both analogues were equipotent to native CCK 26–33 in four bioassays, demonstrating that N-terminal sulfation of CCK 26–33 analogues is compatible with full biological activity.

Changes in opioid receptor selectivity following processing of peptide E: Effect on gut motility

Peptide E is a mu-selective opioid peptide derived from proenkephalin A which contains [Met5]-enkephalin at the amino end and [Leu5]-enkephalin at the carboxyl end. Peptide E is further processed both centrally and peripherally to a [Leu5]-enkephalin-containing fragment which was investigated to determine if processing leads to alterations in receptor selectivity. Peptide E-(15-25) inhibited electrically stimulated contractions in both the mouse vas deferens, longitudinal muscle, myenteric (IC50 = 459 nmol/L), and guinea pig ileum (IC50 = 2630 nmol/L), indicating a sixfold delta-receptor selectivity. When administered intracerebroventricularly to mice, peptide E-(15-25) also produced potent analgesia which was completely antagonized by naloxone pretreatment, but the peptide had no effect on intestinal transit as measured by the radiochromium geometric center method. This is consistent with earlier findings that intracerebroventricular delta-opioid-selective agents are analgesic but do not inhibit intestinal transit. In vitro radioligand binding assays were performed using male Sprague-Dawley rat whole brain homogenates. The IC50 for peptide E against [3H]naloxone was 1.8 nmol/L compared with the delta-opioid ligand, [3H] [D-Pen2, D-Pen5]-enkephalin of 38.8 nmol/L. The IC50 for peptide E-(15-25) against [3H]naloxone was 497 nmol/L, but for [3H] [D-Pen2, D-Pen5]-enkephalin it was 50.6 nmol/L. Therefore, peptide E loses mu-opioid receptor affinity (1.8-497 nmol/L) after proteolytic processing and the loss of the amino terminal tyrosine but maintains a high delta-opioid affinity (38.8-50.6 nmol/L). These studies demonstrate that enzymatic peptide processing of peptide E to peptide E-(15-25) leads to a shift from mu- to delta-receptor selectivity and a different spectrum of biological effects on gut motility.