We have previously described opioid peptidomimetic, 1, employing a tetrahydroquinoline scaffold and modeled on a series of cyclic tetrapeptide opioid agonists. We have recently described modifications to these peptides that confer a mu opioid receptor (MOR) agonist, delta opioid receptor (DOR) antagonist profile, which has been shown to reduce the development of tolerance to the analgesic actions of MOR agonists. Several such bifunctional ligands have been reported, but none has been demonstrated to cross the blood brain barrier. Here we describe the transfer of structural features that evoked MOR agonist/DOR antagonist behavior in the cyclic peptides to the tetrahydroquinoline scaffold and show that the resulting peptidomimetics maintain the desired pharmacological profile. Further, the 4R diastereomer of 1 was fully efficacious and approximately equipotent to morphine in the mouse warm water tail withdrawal assay following intraperitoneal administration and thus a promising lead for the development of opioid analgesics with reduced tolerance.
In a previously described peptidomimetic series, we reported the development of bifunctional µ-opioid receptor (MOR) agonist and δ-opioid receptor (DOR) antagonist ligands with a lead compound that produced antinociception for 1 h after intraperitoneal administration in mice. In this paper, we expand on our original series by presenting two modifications, both of which were designed with the following objectives: 1) probing bioavailability and improving metabolic stability, 2) balancing affinities between MOR and DOR while reducing affinity and efficacy at the Κ-opioid receptor (KOR), and 3) improving in vivo efficacy. Here we establish that through N-acetylation of our original peptidomimetic series, we are able to improve DOR affinity and increase selectivity relative to KOR while maintaining the desired MOR agonist/DOR antagonist profile. From initial in vivo studies, one compound (14a) was found to produce dose-dependent antinociception after peripheral administration with an improved duration of action of longer than 3 h.
Mu opioid receptor (MOR)-targeting analgesics are efficacious pain treatments, but notorious for their abuse potential. In preclinical animal models, coadministration of traditional kappa opioid receptor (KOR)-targeting agonists with MOR-targeting analgesics can decrease reward and potentiate analgesia. However, traditional KOR-targeting agonists are well known for inducing antitherapeutic side effects (psychotomimesis, depression, anxiety, dysphoria). Recent data suggest that some functionally selective, or biased, KOR-targeting agonists might retain the therapeutic effects of KOR activation without inducing undesirable side effects. Nalfurafine, used safely in Japan since 2009 for uremic pruritus, is one such functionally selective KOR-targeting agonist. Here, we quantify the bias of nalfurafine and several other KOR agonists relative to an unbiased reference standard (U50,488) and show that nalfurafine and EOM-salvinorin-B demonstrate marked G protein-signaling bias. While nalfurafine (0.015 mg/kg) and EOM-salvinorin-B (1 mg/kg) produced spinal antinociception equivalent to 5 mg/kg U50,488, only nalfurafine significantly enhanced the supraspinal analgesic effect of 5 mg/kg morphine. In addition, 0.015 mg/kg nalfurafine did not produce significant conditioned place aversion, yet retained the ability to reduce morphine-induced conditioned place preference in C57BL/6J mice. Nalfurafine and EOM-salvinorin-B each produced robust inhibition of both spontaneous and morphine-stimulated locomotor behavior, suggesting a persistence of sedative effects when coadministered with morphine. Taken together, these findings suggest that nalfurafine produces analgesic augmentation, while also reducing opioid-induced reward with less risk of dysphoria. Thus, adjuvant administration of G protein-biased KOR agonists like nalfurafine may be beneficial in enhancing the therapeutic potential of MOR-targeting analgesics, such as morphine.
N-Acetylation of the tetrahydroquinoline (THQ) core of a
series of μ-opioid receptor (MOR) agonist/δ-opioid receptor
(DOR) antagonist ligands increases DOR affinity, resulting in ligands
with balanced MOR and DOR affinities. We report a series of N-substituted THQ analogues that incorporate various carbonyl-containing
moieties to maintain DOR affinity and define the steric and electronic
requirements of the binding pocket across the opioid receptors. 4h produced in vivo antinociception (ip) for 1 h at 10 mg/kg.
The use of opioids for the treatment of pain, while largely effective, is limited by detrimental side effects including analgesic tolerance, physical dependence, and euphoria, which may lead to opioid abuse. Studies have shown that compounds with a μ-opioid receptor (MOR) agonist/δ-opioid receptor (DOR) antagonist profile reduce or eliminate some of these side effects including the development of tolerance and dependence. Herein we report the synthesis and pharmacological evaluation of a series of tetrahydroquinoline-based peptidomimetics with substitutions at the C-8 position. Relative to our lead peptidomimetic with no C-8 substitution, this series affords an increase in DOR affinity and provides greater balance in MOR and DOR binding affinities. Moreover, compounds with carbonyl moieties at C-8 display the desired MOR agonist/DOR antagonist profile whereas alkyl substitutions elicit modest DOR agonism. Several compounds in this series produce a robust antinociceptive effect in vivo and show antinociceptive activity for greater than 2 h after intraperitoneal administration in mice.
In
an effort to expand the structure–activity relationship (SAR)
studies of a series of mixed-efficacy opioid ligands, peptidomimetics
that incorporate methoxy and hydroxy groups around a benzyl or 2-methylindanyl
pendant on a tetrahydroquinoline (THQ) core of the peptidomimetics
were evaluated. Compounds containing a methoxy or hydroxy moiety in
the o- or m-positions increased
binding affinity to the kappa opioid receptor (KOR), whereas compounds
containing methoxy or hydroxy groups in the p-position
decreased KOR affinity and reduced or eliminated efficacy at the mu
opioid receptor (MOR). The results from a substituted 2-methylindanyl
series aligned with the findings from the substituted benzyl series.
Our studies culminated in the development of 8c, a mixed-efficacy
MOR agonist/KOR agonist with subnanomolar binding affinity for both
MOR and KOR.
The present investigations deal with the in vivo effect of different doses of exogenous LH on the RNA- and protein-synthesis in the cerebral cortex, hypothalamus, pituitary, liver, ovary, uterus and adrenal gland of newborn guinea pigs. An increase of 3H-uridine and 3H-leucine incorporation was noted only in the ovary and the uterus. All the other organs showed no response. As early as 1 hour after the injection, LH induced a statistically significant stimulation of amino-acid incorporation into the proteins of the ovary. 2 hours later similar observations were made on the uterus reflecting an induction of uterotrophic steroid biosynthesis in the ovary in response to LH. The lowest effective dose was 5 IU LH/100 g body weight. Furthermore the experiments gave evidence for the dependence of oestrogen synthesis on the ovarian protein formation. The experimental data support the assumption that the ovary of newborn animals is not refractory to stimulation by gonadotrophic hormones. The ovary of newborn guinea pigs shows a relatively low sensitivity against RNA- and protein-synthesis inhibiting substances such as actinomycin and cycloheximide as compared to the liver. The mode of action of LH on the ovary seems to be identical during post partum life and advancing sexual maturation. The existing ovarian gonadotrophin sensitivity indicates that the hypothalamus or possibly the pituitary is primarily responsible for the functional immaturity of the endocrine ovarian control mechanisms during the neonatal period. The restricted functional capacity of the neonatal hypothalamus is characterized by the resistence of this organ to hormones regulating the hypothalamic endocrine function via short and long feedback mechanisms.
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