11 research outputs found
Novel Opioid-Neurotensin-Based Hybrid Peptide with Spinal Long-Lasting Antinociceptive Activity and a Propensity to Delay Tolerance Development
The behavioral responses exerted by spinal administration of the opioid-neurotensin hybrid peptide, PK23, were studied in adult male rats. The antinociceptive effect upon exposure to a thermal stimulus, as well as tolerance development, was assessed in an acute pain model. The PK23 chimera at a dose of 10 nmol/rat produced a potent pain-relieving effect, especially after its intrathecal administration. Compared with intrathecal morphine, this novel compound was found to possess a favourable side effect profile characterized by a reduced scratch reflex, delayed development of analgesic tolerance or an absence of motor impairments when given in the same manner, though some animals died following barrel rotation as a result of its i.c.v. administration (in particular at doses higher than 10 nmol/rat). Nonetheless, these results suggest the potential use of hybrid compounds encompassing both opioid and neurotensin structural fragments in pain management. This highlights the enormous potential of synthetic neurotensin analogues as promising future analgesics
Neurokinin-1 receptor-based bivalent drugs in pain management: The journey to nowhere?
Hybrid compounds (also known as chimeras, designed multiple ligands, bivalent compounds) are chemical units where two active components, usually possessing affinity and selectivity for distinct molecular targets, are combined as a single chemical entity. The rationale for using a chimeric approach is well documented as such novel drugs are characterized by their enhanced enzymatic stability and biological activity. This allows their use at lower concentrations, increasing their safety profile, particularly when considering undesirable side effects. In the group of synthetic bivalent compounds, drugs combining pharmacophores having affinities toward opioid and neurokinin-1 receptors have been extensively studied as potential analgesic drugs. Indeed, substance P is known as a major endogenous modulator of nociception both in the peripheral and central nervous systems. Hence, synthetic peptide fragments showing either agonism or antagonism at neurokinin 1 receptor were both assigned with analgesic properties. However, even though preclinical studies designated neurokinin-1 receptor antagonists as promising analgesics, early clinical studies revealed a lack of efficacy in human. Nevertheless, their molecular combination with enkephalin/endomorphin fragments has been considered as a valuable approach to design putatively promising ligands for the treatment of pain. This paper is aimed at summarizing a 20-year journey to the development of potent analgesic hybrid compounds involving an opioid pharmacophore and devoid of unwanted side effects. Additionally, the legitimacy of considering neurokinin-1 receptor ligands in the design of chimeric drugs is discussed
Mechanisms Underlining Inflammatory Pain Sensitivity in Mice Selected for High and Low Stress-Induced Analgesia—The Role of Endocannabinoids and Microglia
In this work we strived to determine whether endocannabinoid system activity could account for the differences in acute inflammatory pain sensitivity in mouse lines selected for high (HA) and low (LA) swim-stress-induced analgesia (SSIA). Mice received intraplantar injections of 5% formalin and the intensity of nocifensive behaviours was scored. To assess the contribution of the endocannabinoid system, mice were intraperitoneally (i.p.) injected with rimonabant (0.3–3 mg/kg) prior to formalin. Minocycline (45 and 100 mg/kg, i.p.) was administered to investigate microglial activation. The possible involvement of the endogenous opioid system was investigated with naloxone (1 mg/kg, i.p.). Cannabinoid receptor types 1 and 2 (Cnr1, Cnr2) and opioid receptor subtype (Oprm1, Oprd1, Oprk1) mRNA levels were quantified by qPCR in the structures of the central nociceptive circuit. Levels of anandamide (AEA) and 2-arachidonoylglycerol (2-AG) were measured by liquid chromatography coupled with the mass spectrometry method (LC-MS/MS). In the interphase, higher pain thresholds in the HA mice correlated with increased spinal anandamide and 2-AG release and higher Cnr1 transcription. Downregulation of Oprd1 and Oprm1 mRNA was noted in HA and LA mice, respectively, however no differences in naloxone sensitivity were observed in either line. As opposed to the LA mice, inflammatory pain sensitivity in the HA mice in the tonic phase was attributed to enhanced microglial activation, as evidenced by enhanced Aif1 and Il-1β mRNA levels. To conclude, Cnr1 inhibitory signaling is one mechanism responsible for decreased pain sensitivity in HA mice in the interphase, while increased microglial activation corresponds to decreased pain thresholds in the tonic inflammatory phase
Synthesis and binding characteristics of [H-3]neuromedin N, a NTS2 receptor ligand
Neurotensin (NT) and its analog neuromedin N (NN) are formed by the processing of a common precursor in mammalian brain tissue and intestines. The biological effects mediated by NT and NN (e.g. analgesia, hypothermia) result from the interaction with G protein-coupled receptors. The goal of this study consisted of the synthesis and radiolabeling of NN, as well as the determination of the binding characteristics of [H-3]NN and G protein activation by the cold ligand. In homologous displacement studies a weak affinity was determined for NN, with IC50 values of 454 nM in rat brain and 425 nM in rat spinal cord membranes. In saturation binding experiments the Kd value proved to be 264.8 +/- 30.18 nM, while the B-max value corresponded to 3.8 02 pmol/mg protein in rat brain membranes. The specific binding of [H-3]NN was saturable, interacting with a single set of homogenous binding sites. In sodium sensitivity experiments, a very weak inhibitory effect of Na+ ions was observed on the binding of resulting in an IC50 of 150.6 inM. In [S-35]GTP gamma S binding experiments the E-max value was 112.3 +/- 1.4% in rat brain and 112.9 +/- 2.4% in rat spinal cord membranes and EC50 values of 0.7 nM and 0.79 nM were determined, respectively. NN showed moderate agonist activities in stimulating G proteins. The stimulatory effect of NN could be maximally inhibited via use of the NTS2 receptor antagonist levocabastine, but not by the opioid receptor specific antagonist naloxone, nor by the NTS1 antagonist SR48692. These observations allow us to conclude that [H-3]NN labels NTS2 receptors in rat brain membranes. (C) 2015 Elsevier Ltd. All rights reserved
Antinociceptive effect induced by a combination of opioid and neurotensin moieties vs. their hybrid peptide [Ile(9)]PK20 in an acute pain treatment in rodents.
Hybrid compounds are suggested to be a more effective remedy for treatment of various diseases than combination therapy, since the attenuation or total disappearance of side effects, typically induced by a single moiety, can be observed. This is of great importance, especially when we consider problems resulting from the use of opioid analgesics. However, although it seems that such compounds can be valuable therapeutic tools, the lack of conviction among the public as to the appropriateness of their use still remains; therefore patients are commonly treated with polypharmacy. Thus, in the presented paper we show a comparison of the antinociceptive effect between a novel opioid-neurotensin chimera called [Ile(9)]PK20 and a mixture of its structural elements, delivered intrathecally and systemically. Additionally, motor coordination was assessed in the rotarod test. The results clearly indicate that spinal administration of the examined compounds, resulted in a long-lasting, dose- and time-dependent antinociceptive effect. Although the mixture of both pharmacophores was found to be more active than [Ile(9)]PK20, motor impairments surfaced as a side effect. This in turn illustrates the advantageous use of hybrid structures over drug cocktails
Biological evaluation and molecular docking studies of AA3052, a compound containing a ÎĽ-selective opioid peptide agonist DALDA and d-Phe-Phe-d-Phe-Leu-Leu-NH2, a substance P analogue
The design of novel drugs for pain reliefwith improved analgesic properties and diminished side effect induction
profile still remains a challenging pursuit. Tolerance is one of themost burdensomephenomena thatmay hamper
ongoing opioid therapy, especially in chronic pain patients. Therefore, a promising strategy of hybridizing two
pharmacophores that target distinct binding sites involved in pain modulation and transmissionwas established.
Previous studies have led to the development of opioid agonist/NK1 agonist hybrids that produce sufficient analgesia
and also suppress opioid-induced tolerance development. In our present investigation we assessed the
antinociceptive potency of a new AA3052 chimera comprised of a potent MOR selective dermorphin derivative
(DALDA) and an NK1 agonist, a stabilized substance P analogue. We have shown that AA3052 significantly
prolonged responses to both mechanical and noxious thermal stimuli in rats after intracerebroventricular administration.
Additionally, AA3052 did not trigger the development of tolerance in a 6-day daily injection paradigm
nor did it produce any sedative effects, as assessed in the rotarod performance test. However, the antinociceptive
effect of AA3052 was independent of opioid receptor stimulation by the DALDA pharmacophore as shown in the
agonist-stimulated G-protein assay. Altogether the current results confirm the antinociceptive effectiveness of a
novel opioid/SP hybrid agonist, AA3052, and more importantly its ability to inhibit the development of tolerance