Pain remains a pervasive problem throughout medicine, transcending all specialty boundaries. Despite the extraordinary insights into pain and its mechanisms over the past few decades, few advances have been made with analgesics. Most pain remains treated by opiates, which have significant side effects that limit their utility. We now describe a potent opiate analgesic lacking the traditional side effects associated with classical opiates, including respiratory depression, significant constipation, physical dependence, and, perhaps most important, reinforcing behavior, demonstrating that it is possible to dissociate side effects from analgesia. Evidence indicates that this agent acts through a truncated, six-transmembrane variant of the G protein-coupled mu opioid receptor MOR-1. Although truncated splice variants have been reported for a number of G protein-coupled receptors, their functional relevance has been unclear. Our evidence now suggests that truncated variants can be physiologically important through heterodimerization, even when inactive alone, and can comprise new therapeutic targets, as illustrated by our unique opioid analgesics with a vastly improved pharmacological profile.opiate receptor | rewarding behavior | kappa 3 receptor T he utility of opioids in the management of pain is not disputed, but they come at a price. Along with their ability to relieve pain comes a variety of opioid receptor-mediated side effects, including respiratory depression, constipation, physical dependence, and reward behavior felt by many to contribute to their addictive potential. Most of the clinical opioids act through mu receptors, which mediate both analgesia and these side effects. Pharmacological studies have long suggested subtypes of mu receptors (1) and the possibility of dissociating analgesia from respiratory depression (2, 3), physical dependence (4), and the inhibition of gastrointestinal transit (5, 6). However, attempts to develop opiate analgesics that avoid these side effects have not been very fruitful. The isolation of a series of splice variants of the cloned mu opioid receptor from mice ( Fig. 1), rats, and humans with similar splicing patterns (7, 8) reveals a complexity far exceeding the pharmacological classification of mu receptor subtypes (1). However, this complexity has yet to be exploited in generating new classes of opioid analgesics. We now report an unexpected and unusual target for potent opioid analgesic drugs that lack respiratory depression, physical dependence, reward behavior, and significant constipation. ResultsRecently, we synthesized iodobenzoylnaltrexamide (IBNtxA), a naltrexone derivative (Fig. 2) (9). In vivo, it is a very potent analgesic (ED 50 = 0.48 ± 0.05 mg/kg s.c.) (Fig. 3A and Fig. S1), ∼10-fold more potent than morphine (4.6 ± 0.97 mg/kg s.c.) (10), with a mechanism of action quite distinct from traditional opiates. It was active s.c. as well as orally (Fig. S1), with a peak effect after oral administration that was delayed relative to parenteral administration. In ...
Ligands modulate opioid actions in vivo, with agonists diminishing morphine analgesia and antagonists enhancing the response. Using human BE (2)
3-Iodobenzoylnaltrexamide 1 (IBNtxA) is a potent analgesic acting through a novel receptor target that lack many side-effects of traditional opiates composed, in part, of exon 11-associated truncated six transmembrane domain MOR-1 (6TM/E11) splice variants. To better understand the SAR of this drug target, a number of 4,5-epoxymorphinan analogues were synthesized. Results show the importance of a free 3-phenolic group, a phenyl ring at the 6 position, an iodine at the 3′or 4′ position of the phenyl ring, and an N-allyl or c-propylmethyl group to maintain high 6TM/E11 affinity and activity. 3-Iodobenzoylnaloxamide 15 (IBNalA) with a N-allyl group displayed lower δ opioid receptor affinity than its naltrexamine analogue, was 10-fold more potent an analgesic than morphine, elicited no respiratory depression or physical dependence, and only limited inhibition of gastrointestinal transit. Thus, the aryl-naloxamide scaffold can generate a potent analgesic acting through the 6TM/E11 sites with advantageous side-effect profile and greater selectivity.
Tritiated opioid radioligands have proven valuable in exploring opioid binding sites. However, tritium has many limitations. Its low specific activity and limited counting efficiency makes it difficult to examine low abundant, high affinity sites and its disposal is problematic due to the need to use organic scintillants and its relatively long half-life. To overcome these issues, we have synthesized both unlabeled and carrier-free radioiodinated iodobenzoyl derivatives of 6β-naltrexamine (125I-BNtxA, 18), 6β-naloxamine (125I-BNalA, 19) and 6β-oxymorphamine (125I-BOxyA, 20) with specific activities of 2100 Ci/mmol. To optimize the utility of the radioligand, we designed a synthesis in which the radiolabel is incorporated in the last synthetic step, which required the selective iodination of the benzoyl moiety without incorporation into the phenolic A ring. Competition studies demonstrated high affinity of the unlabelled compounds for opioid receptors in transfected cell lines, as did the direct binding of the 125I-ligands to the opioid receptors. The radioligand displayed very high sensitivity, enabling a marked reduction in tissue, as well as excellent signal/noise characteristics. These new 125I-radioligands should prove valuable in future studies of opioid binding sites.
A vast number of opioid peptides are derived from processing of precursors from three separate genes. The prodynorphin gene generates dynorphin A, the predominant product and the natural ligand for the kappa1 opioid receptor. However, other products of this gene have also been identified, including dynorphin B and α‐neoendorphin. Studies of kappa receptors have utilized 3H‐U69,593, a highly selective drug with poor affinity for both mu and delta opioid receptors. However, evidence suggests that 3H‐U69,593 may be labeling more than one class of kappa receptor in brain tissue. Further exploration of these binding sites requires the development of novel radioligands. In an effort to further the characterization of these potential kappa receptor subtypes, we have developed 125I‐labeled opioid peptides with high affinity and established receptor binding assays for them. Funded by grants to GWP (DA0641, DA07242, DA02615 and DA00220) and a training grant to JEP (DA07274) from the National Insitute on Drug Abuse.
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