Enzymatic degradation of endomorphins.

Centrally acting plant opiates, such as morphine, are the most frequently used analgesics for the relief of severe pain, even though their undesired side effects are serious limitation to their usefulness. The search for new therapeutics that could replace morphine has been mainly focused on the development of peptide analogs or peptidomimetics with high selectivity for one receptor type and high bioavailability, that is good blood-brain barrier permeability and enzymatic stability. Drugs, in order to be effective, must be able to reach the target tissue and to remain metabolically stable to produce the desired effects. The study of naturally occurring peptides provides a rational and powerful approach in the design of peptide therapeutics. Endogenous opioid peptides, endomorphin-1 and endomorphin-2, are two potent and highly selective mu-opioid receptor agonists, discovered only a decade ago, which display potent analgesic activity. However, extensive studies on the possible use of endomorphins as analgesics instead of morphine met with failure due to their instability. This review deals with the recent investigations that allowed determine degradation pathways of endomorphins in vitro and in vivo and propose modifications that will lead to more stable analogs.

Synthesis and biological activity of endomorphin-2 analogs incorporating piperidine-2-, 3- or 4-carboxylic acids instead of proline in position 2.

Novel endomorphin-2 (EM-2) analogs have been synthesized, incorporating unnatural amino acids with six-membered heterocyclic rings, such as piperidine-2-, 3- and 4-carboxylic acids (Pip, Nip and Inp, respectively) instead of Pro in position 2. [(R)-Nip(2)]EM-2 displayed an extremely high affinity for the mu-opioid receptor with IC(50) = 0.04 +/- 0.01 nM in comparison with IC(50) = 0.69 +/- 0.03 nM for EM-2. This analog was also very potent in the aequorin luminescence-based functional calcium assay and showed significantly enhanced stability in rat brain homogenate.

Novel highly potent mu-opioid receptor antagonist based on endomorphin-2 structure.

The mu-opioid agonists endomorphin-1 (Tyr-Pro-Trp-Phe-NH(2)) and endomorphin-2 (Tyr-Pro-Phe-Phe-NH(2)) exhibit an extremely high selectivity for the mu-opioid receptor and thus represent a potential framework for modification into mu-antagonists. Here we report on the synthesis and biological evaluation of novel [d-2-Nal(4)]endomorphin-2 analogs, [Sar(2),d-2-Nal(4)]endomorphin-2 and [Dmt(1),Sar(2),d-2-Nal(4)]endomorphin-2 (Dmt=2'6'-dimethyltyrosine; Sar=N-methylglycine, sarcosine; d-2-Nal=3-(2-naphthyl)-d-alanine). [Dmt(1),Sar(2),d-2-Nal(4)]endomorphin-2 possessed very high affinity for the mu-opioid receptor (IC(50)=0.01+/-0.001 nM) and turned out to be a potent and extremely selective mu-opioid receptor antagonist, as judged by the in vitro aequorin luminescence-based calcium assay (pA(2)=9.19). However, in the in vivo hot plate test in mice this analog was less potent than our earlier mu-opioid receptor antagonist, [Dmt(1),d-2-Nal(4)]endomorphin-2 (antanal-2). The exceptional mu-opioid receptor in vitro activity and selectivity of [Dmt(1), Sar(2),d-2-Nal(4)]endomorphin-2 makes this analog a valuable pharmacological tool, but further modifications are needed to improve its in vivo profile.

Mu-opioid receptor ligands lack receptor subtype selectivity in the aequorin luminescence-based calcium assay.

The aim of the present study was to characterize the binding selectivity of the mu-opioid receptor ligands, endomorphin-1, endomorphin-2, and DAMGO, in the in vitro functional assay, based on the changes in intracellular calcium levels. For the experiments Chinese hamster ovary cells, stably expressing human mu-receptor, were used. The mu-agonist-induced calcium responses were significantly inhibited by naloxone, an opioid antagonist with high preference for the mu-opioid receptors. Naloxonazine, a mu1-non-peptide antagonist, inhibited the effect of all tested mu-agonists. However, there was no significant difference in the antagonist effect of naloxonazine on the calcium response induced by mu1- (endomorphin-2) and mu2-agonists (endomorphin-1, DAMGO). [D-Pro2]endomorphin-1 and [D-Pro2]endomorphin-2, putative peptide mu2- and mu1-antagonists, respectively, which had been shown in vivo to inhibit the antinociception induced by mu-agonists, produced no inhibitory effect in our in vitro experiments. Our results demonstrated that there is only one population of the mu-opioid receptors expressed in the Chinese hamster ovary cells. We suggest that the mu-opioid receptors form a homogenous population in the in vitro systems. However, the existence of mu-receptor subtypes in vivo is still pharmacologically possible.

Endomorphin analogs.

Opiate alkaloids, such as morphine, are powerful analgesic agents that are the drugs of choice for the treatment of severe pain. The pharmacological effects of opiates are mediated through the binding and activation of membrane-bound opioid receptors that are found in the central and peripheral nervous systems. Opioid receptors have been classified into three different types, mu, delta and kappa, and are activated by the specific ligands. It has been demonstrated that the most potent antinociceptive effects are mediated by the mu-receptor. However, until 1997 no endogenous ligand for this receptor was known. The identification of endomorphins opened a new era in the research of the mu-opioid system. They are the first reported brain peptides that label mu-receptor with high affinity and selectivity and therefore are proposed as the endogenous mu-opioid receptor ligands. Morphine and endomorphins act as agonists at the same mu-opioid receptor, but the latter are thought to inhibit pain without some of the undesired side-effects of plant opiates. This observation encouraged extensive studies on the possible use of endomorphin analogs as analgesics instead of morphine. This review summarizes a decade of research on structure-activity relationship studies of endomorphin analogs, aimed at obtaining compounds with increased bioavailability, in particular with better barrier penetration and resistance against enzymatic degradation. Chemical modifications that led to obtaining potent and selective agonists and antagonists based on the structure of endomorphins are discussed.