Elizabeth Bolan

Retention of heroin and morphine–6β–glucuronide analgesia in a new line of mice lacking exon 1 of MOR–1

Morphine produces analgesia by activating mu opioid receptors encoded by the MOR–1 gene. Although morphine–6β–glucuronide (M6G), heroin and 6–acetylmorphine also are considered mu opioids, recent evidence suggests that they act through a distinct receptor mechanism. We examined this question in knockout mice containing disruptions of either the first or second coding exon of MOR–1. Mice homozygous for either MOR–1 mutation were insensitive to morphine. Heroin, 6–acetylmorphine and M6G still elicited analgesia in the exon–1 MOR–1 mutant, which also showed specific M6G binding, whereas M6G and 6–acetylmorphine were inactive in the exon–2 MOR–1 mutant. These results provide genetic evidence for a unique receptor site for M6G and heroin analgesia.

Generation of the mu opioid receptor (MOR-1) protein by three new splice variants of the Oprm gene

Using 5′ RACE, we have isolated four additional exons of the mu opioid receptor gene (Oprm), resulting in a gene spanning over 250 kb. The four new exons are contained within eight additional splice variants containing exon 11 at the 5′ terminus. Exon 11, which is under the control of a previously unknown upstream promoter, and exon 12 are located ≈10 kb and ≈8 kb upstream from exon 1, respectively. Exon 13 and 14 are located between exons 1 and 2. The regional distributions of the variants, as determined by reverse transcription-PCR, varied among themselves and were distinct from that of MOR-1, implying region-specific RNA processing. Three variants (MOR-1H, MOR-1I, and MOR-1J) contained two potential translational start points, with the translational start point in exon 1 producing proteins identical to the original MOR-1 protein. When expressed, the receptor binding of these three variants was indistinguishable from that of MOR-1. The remaining eight proteins using the translation start point in exon 11 were all truncated, with three (MOR-1G, MOR-1M, and MOR-1N) predicting proteins of only six transmembrane domains and the rest giving proteins under 10 kDa. Western blots with an exon 11-specific antiserum revealed bands consistent with the six transmembrane domain proteins within the brain, but the shorter proteins were not detected. Thus, the MOR-1 protein can be generated by four different splice variants of the Oprm gene under the control of two physically distinct promoters. Although the truncated proteins are expressed in brain with a unique regional distribution, their functional significance remains unknown.

Retention of heroin and morphine-6 beta-glucuronide analgesia in a new line of mice lacking exon 1 of MOR-1.

Morphine produces analgesia by activating mu opioid receptors encoded by the MOR–1 gene. Although morphine–6β–glucuronide (M6G), heroin and 6–acetylmorphine also are considered mu opioids, recent evidence suggests that they act through a distinct receptor mechanism. We examined this question in knockout mice containing disruptions of either the first or second coding exon of MOR–1. Mice homozygous for either MOR–1 mutation were insensitive to morphine. Heroin, 6–acetylmorphine and M6G still elicited analgesia in the exon–1 MOR–1 mutant, which also showed specific M6G binding, whereas M6G and 6–acetylmorphine were inactive in the exon–2 MOR–1 mutant. These results provide genetic evidence for a unique receptor site for M6G and heroin analgesia.

Endogenous κ-Opioid Receptor Systems Regulate Mesoaccumbal Dopamine Dynamics and Vulnerability to Cocaine

Genetic and pharmacological approaches were used to examine κ-opioid receptor (KOR-1) regulation of dopamine (DA) dynamics in the nucleus accumbens and vulnerability to cocaine. Microdialysis revealed that basal DA release and DA extraction fraction (Ed), an indirect measure of DA uptake, are enhanced in KOR-1 knock-out mice. Analysis of DA uptake revealed a decreased Km but unchanged Vmax in knock-outs. Knock-out mice exhibited an augmented locomotor response to cocaine, which did not differ from that of wild-types administered a behavioral sensitizing cocaine treatment. The ability of cocaine to increase DA was enhanced in knock-outs, whereas c-fos induction was decreased. Although repeated cocaine administration to wild types produced behavioral sensitization, knock-outs exhibited no additional enhancement of behavior. Administration of the long-acting KOR antagonist nor-binaltorphimine to wild-type mice increased DA dynamics. However, the effects varied with the duration of KOR-1 blockade. Basal DA release was increased whereas Ed was unaltered after 1 h blockade. After 24 h, release and Ed were increased. The behavioral and neurochemical effects of cocaine were enhanced at both time points. These data demonstrate the existence of an endogenous KOR-1 system that tonically inhibits mesoaccumbal DA neurotransmission. Its loss induces neuroadaptations characteristic of “cocaine-sensitized” animals, indicating a critical role of KOR-1 in attenuating responsiveness to cocaine. The increased DA uptake after pharmacological inactivation or gene deletion highlights the plasticity of mesoaccumbal DA neurons and suggests that loss of KOR-1 and the resultant disinhibition of DA neurons trigger short- and long-term DA transporter adaptations that maintain normal DA levels, despite enhanced release.

Isolation and expression of a novel alternatively spliced mu opioid receptor isoform, MOR-1F

The MOR‐1 gene is large, with a recent study reporting nine exons spanning 250 kb which combine to yield six different mu opioid receptor splice variants. We now report the isolation of exon 10, which is contained within yet another splice variant, MOR‐1F, which is composed of exons 1, 2, 3, 10, 6, 7, 8 and 9. Exon 10 comprises 186 bp which predict a unique 58 amino acid sequence extending beyond exon 3. It has been mapped between exons 4 and 6 and has flanking consensus splice sequences. On Northern blot analysis, the MOR‐1F mRNA is smaller than the other MOR‐1 mRNAs. When expressed in CHO cells, MOR‐1F binds the mu opioid radioligand [3H]DAMGO with high affinity (K D=1.04±0.03 nM). Competition studies demonstrated the selectivity of the variant for mu opioid ligands, supporting its classification within the mu opioid receptor family.

Regulation of Dopamine Transporter Function and Cell Surface Expression by D3 Dopamine Receptors

D3 dopamine receptors are expressed by dopamine neurons and are implicated in the modulation of presynaptic dopamine neurotransmission. The mechanisms underlying this modulation remain ill defined. The dopamine transporter, which terminates dopamine transmission via reuptake of released neurotransmitter, is regulated by receptor- and second messenger-linked signaling pathways. Whether D3 receptors regulate dopamine transporter function is unknown. We addressed this issue using a fluorescent imaging technique that permits real time quantification of dopamine transporter function in living single cells. Accumulation of the fluorescent dopamine transporter substrate trans-4-[4-(dimethylamino)styryl]-1-methylpyridinium (ASP+) in human embryonic kidney cells expressing human dopamine transporter was saturable and temperature-dependent. In cells co-expressing dopamine transporter and D3 receptors, the D2/D3 agonist quinpirole produced a rapid, concentration-dependent, and pertussis toxin-sensitive increase of ASP+ uptake. Similar agonist effects were observed in Neuro2A cells and replicated in human embryonic kidney cells using a radioligand uptake assay in which binding to and activation of D3 receptors by [3H]dopamine was prevented. D3 receptor stimulation activated phosphoinositide 3-kinase and MAPK. Inhibition of either kinase prevented the quinpirole-induced increase in uptake. D3 receptor activation differentially affected dopamine transporter function and subcellular distribution depending on the duration of agonist exposure. Biotinylation experiments revealed that the rapid increase of uptake was associated with increased cell surface and decreased intracellular expression and increased dopamine transporter exocytosis. In contrast, prolonged agonist exposure reduced uptake and transporter cell surface expression. These results demonstrate that D3 receptors regulate dopamine transporter function and identify a novel mechanism by which D3 receptors regulate extracellular dopamine concentrations.

Pharmacological characterization of morphine-6-sulfate and codeine-6-sulfate.

Morphine-6-sulfate (M6S) and codeine-6-sulfate (C6S) are mu-selective opiates which have been isolated from brain. M6S is an effective analgesic, with a 30-fold greater potency than morphine in the mouse radiant heat tailflick assay and similar to the active morphine metabolite morphine-6beta-glucuronide (M6G). M6S analgesia is reversed by 3-methoxynaltrexone at low antagonist doses which are inactive against morphine, suggesting that M6S may be acting through the same mechanisms as M6G. Consistent with this possibility, antisense mapping of the MOR-1 clone revealed that M6S analgesia was lowered by probes targeting exon 2 and not by targeting exon 1, a sensitivity profile similar to that of M6G and not morphine. C6S also has analgesic activity at doses approximately 10-fold greater than M6S. However, its characterization was impeded by the appearance of seizures at doses below full analgesic activity. Thus, M6S is a potent analgesic with pharmacological properties similar to M6G. C6S has limited utility due to its high level of toxicity.

Retention of heroin and morphine|[ndash]|6|[beta]||[ndash]|glucuronide analgesia in a new line of mice lacking exon 1 of MOR|[ndash]|1

Morphine produces analgesia by activating mu opioid receptors encoded by the MOR–1 gene. Although morphine–6β–glucuronide (M6G), heroin and 6–acetylmorphine also are considered mu opioids, recent evidence suggests that they act through a distinct receptor mechanism. We examined this question in knockout mice containing disruptions of either the first or second coding exon of MOR–1. Mice homozygous for either MOR–1 mutation were insensitive to morphine. Heroin, 6–acetylmorphine and M6G still elicited analgesia in the exon–1 MOR–1 mutant, which also showed specific M6G binding, whereas M6G and 6–acetylmorphine were inactive in the exon–2 MOR–1 mutant. These results provide genetic evidence for a unique receptor site for M6G and heroin analgesia.