Karen M. Kedzie

Molecular cloning and expression of human EP3 receptors: evidence of three variants with differing carboxyl termini.

1 The polymerase chain reaction (PCR) was used in combination with plaque hybridization analysis to clone four variants of the EP3 prostaglandin receptor from a human small intestine cDNA library. 2 Three of these variants, i.e. the EP3A, EP3E and EP3D, share the same primary amino acid sequence except for their carboxyl termini, which diverge from one another at the same point, approximately 10 amino acids away from the end of the seventh membrane spanning domain of the receptor. The fourth variant (EP3A1) has a nucleotide coding sequence identical to EP3A but has a completely different 3′;untranslated sequence. 3 The carboxyl termini of the three isoforms differ most obviously in length with the EP3A being the longest (41 amino acids) and the EP3E being the shortest (16 amino acids). They also differ in content with the EP3A containing 9 serine and threonines in its carboxyl terminus and the EP3E none. 4 Transient expression in eukaryotic cells showed that the human EP3 receptor variants had similar but not identical radioligand binding properties and differed in their functional coupling to second messenger pathways. Up to 3 pmol mg−1 protein of [3H]‐prostaglandin E2 binding could be obtained with more than 95% specific binding. Using a reporter gene assay, as a measure of intracellular cyclic AMP levels, the EP3A coupled more efficiently to the inhibition of adenylyl cyclase than did the EP3E. 5 PCR was used to confirm the presence of mRNAs encoding the four human EP3 receptor variants in tissues of the human small intestine, heart and pancreas. These findings indicate that the EP3 receptor variants identified here are likely to be expressed in tissues. The differences in the carboxyl termini at the protein level, and in the 3′ untranslated regions at the mRNA level, could be profound in terms of the regulation and functional coupling of these receptor isoforms.

Replacement of the carboxylic acid group of prostaglandin F2α with a hydroxyl or methoxy substituent provides biologically unique compounds

Replacement of the carboxylic acid group of PGF2α with the non‐acidic substituents hydroxyl (‐OH) or methoxy (‐OCH3) resulted in an unexpected activity profile. Although PGF2α 1‐OH and PGF2α 1‐OCH3 exhibited potent contractile effects similar to 17‐phenyl PGF2α in the cat lung parenchymal preparation, they were approximately 1000 times less potent than 17‐phenyl PGF2α in stimulating recombinant feline and human FP receptors. In human dermal fibroblasts and Swiss 3T3 cells PGF2α 1‐OH and PGF2α 1‐OCH3 produced no Ca2+ signal until a 1 μM concentration was exceeded. Pretreatment of Swiss 3T3 cells with either 1 μM PGF2α 1‐OH or PGF2α 1‐OCH3 did not attenuate Ca2+ signal responses produced by PGF2α or fluprostenol. In the rat uterus, PGF2α 1‐OH was about two orders of magnitude less potent than 17‐phenyl PGF2α whereas PGF2α 1‐OCH3 produced only a minimal effect. Radioligand binding studies on cat lung parenchymal plasma membrane preparations suggested that the cat lung parenchyma does not contain a homogeneous population of receptors that equally respond to PGF2α1‐OH, PGF2α1‐OCH3, and classical FP receptor agonists. Studies on smooth muscle preparations and cells containing DP, EP1, EP2, EP3, EP4, IP, and TP receptors indicated that the activity of PGF2α 1‐OH and PGF2α 1‐OCH3 could not be ascribed to interaction with these receptors. The potent effects of PGF2α 1‐OH and PGF2α 1‐OCH3 on the cat lung parenchyma are difficult to describe in terms of interaction with the FP or any other known prostanoid receptor.

α-1-Adrenergic Receptor Agonist Activity of Clinical α-Adrenergic Receptor Agonists Interferes with α-2-Mediated Analgesia

Background:The use of &agr;-2 adrenergic agonists for analgesia is limited due to a narrow therapeutic window. Definition of the role of alpha receptor subtypes in alpha agonist mediated analgesia may identify strategies to separate the analgesic from sedative and cardiovascular effects. Methods:Analgesic activity of brimonidine, clonidine, and tizanidine was investigated in wild-type C57B/6, &agr;-2A, and &agr;-2C knockout mice with allodynia induced by N-methyl-D-aspartate or sulprostone. The alpha receptor selectivity of the alpha agonists was assessed using functional in vitro recombinant assays. Results:Brimonidine, clonidine, and tizanidine reduced N-methyl-D-aspartate- and sulprostone-induced allodynia in wild-type mice, but not &agr;-2A knockout mice. In &agr;-2C knockout mice, brimonidine and tizanidine reduced allodynia in both models, whereas clonidine only reduced N-methyl-D-aspartate-induced allodynia. In vitro, clonidine and tizanidine activated &agr;-1 and &agr;-2 receptors with similar potencies, whereas brimonidine was selective for &agr;-2 receptors. In &agr;-2C knockout mice with sulprostone-induced allodynia, blockade of clonidine’s &agr;-1 receptor agonist activity restored clonidine’s analgesic efficacy. In wild-type mice, the analgesic potency of intrathecal clonidine and tizanidine was increased 3- to 10-fold by coadministration with the &agr;-1A-selective antagonist 5-methylurapidil without affecting sedation. Following intraperitoneal administration, the therapeutic window was negligible for clonidine and tizanidine, but greater for brimonidine. 5-Methylurapidil enhanced the therapeutic window of intraperitoneal clonidine and tizanidine approximately 10-fold. Conclusions:&agr;-1A receptor agonist activity can counterbalance &agr;-2 receptor agonist-induced analgesia. Greater &agr;-2 selectivity may enhance the therapeutic window of &agr;-2 agonists in the treatment of pain.

Functional expression of mammalian cytochromes P450IIB in the yeast Saccharomyces cerevisiae

Three mammalian cytochromes P450 from the IIB subfamily, P450IIB11 from canine and P450IIB4 and P450IIB5 from rabbit, have been expressed in the yeast Saccharomyces cerevisiae by use of an autonomously replicating vector containing the galactose-inducible gal10 promoter. Cytochromes P450IIB4 and P450IIB5 are closely related proteins, with only 11 amino acid substitutions between them. P450IIB11 is a homologous protein, likely orthologous with IIB4 or IIB5, with 102 amino acid substitutions compared with the P450IIB4 protein and 106 compared with the P450IIB5 protein. The expressed proteins are functional in yeast microsomes, exhibiting activity toward androstenedione, 7-ethoxycoumarin, and, in some cases, progesterone. Expressed cytochromes P450IIB4 and P450IIB11 hydroxylate androstenedione with regio- and stereoselectivity characteristic of the purified, reconstituted proteins. A striking difference in the androstenedione metabolite profiles of IIB4 and IIB5 was observed, with IIB4 producing almost exclusively the 16 beta-hydroxy metabolite and IIB5 producing the 16 alpha-hydroxy and 15 alpha-hydroxy products. This is the first time that 15 alpha-hydroxylase activity has been associated with IIB4/IIB5. This activity has also been detected in liver microsomes from some, but not all, individual phenobarbital-induced rabbits tested and is largely inhibited by anti-rabbit P450IIB immunoglobulin G. These studies illustrate the utility of the yeast expression system for defining catalytic activities of individual mammalian cytochromes P450 and identifying new marker activities that can be utilized in liver microsomes.

Flavin-containing monooxygenase S-oxygenation of a series of thioureas and thiones

Mammalian flavin-containing monooxygenase (FMO) is active towards many drugs with a heteroatom having the properties of a soft nucleophile. Thiocarbamides and thiones are S-oxygenated to the sulfenic acid which can either react with glutathione and initiate a redox-cycle or be oxygenated a second time to the unstable sulfinic acid. In this study, we utilized LC-MS/MS to demonstrate that the oxygenation by hFMO of the thioureas under test terminated at the sulfenic acid. With thiones, hFMO catalyzed the second reaction and the sulfinic acid rapidly lost sulfite to form the corresponding imidazole. Thioureas are often pulmonary toxicants in mammals and, as previously reported by our laboratory, are excellent substrates for hFMO2. This isoform is expressed at high levels in the lung of most mammals, including non-human primates. Genotyping to date indicates that individuals of African (up to 49%) or Hispanic (2-7%) ancestry have at least one allele for functional hFMO2 in lung, but not Caucasians nor Asians. In this study the major metabolite formed by hFMO2 with thioureas from Allergan, Inc. was the sulfenic acid that reacted with glutathione. The majority of thiones were poor substrates for hFMO3, the major form in adult human liver. However, hFMO1, the major isoform expressed in infant and neonatal liver and adult kidney and intestine, readily S-oxygenated thiones under test, with Kms ranging from 7 to 160 μM and turnover numbers of 30-40 min(-1). The product formed was identified by LC-MS/MS as the imidazole. The activities of the mouse and human FMO1 and FMO3 orthologs were in good agreement with the exception of some thiones for which activity was much greater with hFMO1 than mFMO1.