MP-13, a novel chimeric peptide of morphiceptin and pepcan-9, produces potent antinociception with limited side effects.

Pharmacological investigations have substantiated the potential of bifunctional opioid/cannabinoid agonists in delivering potent analgesia while minimizing adverse reactions. Peptide modulators of cannabinoid receptors, known as pepcans, have been investigated before. In this study, we designed a series of chimeric peptides based on pepcans and morphiceptin (YPFP-NH2). Here, we combined injections of pepcans and morphiceptin to investigate the combination treatment of opioids and cannabis and compared the analgesic effect with chimeric compounds. Subsequently, we employed computational docking to screen the compounds against opioid and cannabinoid receptors, along with an acute pain model, to identify the most promising peptide. Among these peptides, MP-13, a morphiceptin and pepcan-9 (PVNFKLLSH) construct, exhibited superior supraspinal analgesic efficacy in the tail-flick test, with an ED50 value at 1.43 nmol/mouse, outperforming its parent peptides and other chimeric analogs. Additionally, MP-13 displayed potent analgesic activity mediated by mu-opioid receptor (MOR), delta-opioid receptor (DOR), and cannabinoid type 1 (CB1) receptor pathways. Furthermore, MP-13 did not induce psychological dependence and gastrointestinal motility inhibition at the effective analgesic doses, and it maintained non-tolerance-forming antinociception throughout a 7-day treatment regimen, with an unaltered count of microglial cells in the periaqueductal gray region, supporting this observation. Moreover, intracerebroventricular administration of MP-13 demonstrated dose-dependent antinociception in murine models of neuropathic, inflammatory, and visceral pain. Our findings provide promising insights for the development of opioid/cannabinoid peptide agonists, addressing a crucial gap in the field and holding significant potential for future research and development. PERSPECTIVE: This article offers insights into the combination treatment of pepcans with morphiceptin. Among the chimeric peptides, MP-13 exhibited potent analgesic effects in a series of preclinical pain models with a favorable side-effect profile.

Thiol-Michael addition based conjugate for glutathione activation and release.

Glutathione (GSH) level has long been recognized as a valuable tumor biomarker. GSH-mediated activation and release systems have been extensively developed for cancer diagnosis and treatment, but mainly focused on disulfide-based conjugate. We reported here a new thiol-Michael addition based GSH response conjugate TC6, which consists of a unique tricyclic structure containing α, ß-unsaturated ketone responsive groups. The conjugate was easily synthesized and showed good selectivity to glutathione with certain stability. The camptothecin delivery experiment of TC6 showed improved anti-tumor ability in cells and tumor-bearing mice. TC6 could be used for the development of antibody or small molecule conjugated drugs.

MCRT, a multifunctional ligand of opioid and neuropeptide FF receptors, attenuates neuropathic pain in spared nerve injury model.

Chimeric peptide MCRT (YPFPFRTic-NH2 ) was a multifunctional ligand of opioid and neuropeptide FF (NPFF) receptors and reported to be potentially antalgic in acute tail-flick test. Here, we developed spared nerve injury (SNI) model to explore its efficacy in chronic neuropathic pain. Analgesic tolerance, opioid-induced hyperalgesia and gastrointestinal transit were measured for safety evaluation. Intracerebroventricular (i.c.v.) and intraplantar (i.pl.) injections were conducted as central and peripheral routes, respectively. Results demonstrated that MCRT alleviated neuropathic pain effectively and efficiently, with the ED50 values of 4.93 nmol/kg at the central level and 3.11 nmol/kg at the peripheral level. The antagonist blocking study verified the involvement of mu-, delta-opioid and NPFF receptors in MCRT produced anti-allodynia. Moreover, the separation of analgesia from unwanted effects was preliminarily achieved and that MCRT caused neither analgesic tolerance nor hyperalgesia after chronic i.c.v. administration, nor constipation after i.pl. administration. Notably, the local efficacy of MCRT in SNI mice was about one thousandfold higher than morphine and ten thousandfold higher than pregabalin, indicating a great promise in the future treatment of neuropathic pain.

Studies on the changes of uPA system in a co-culture model of bone marrow stromal cells-leukemia cells.

The core of the tumor microenvironment in the hematological system is formed by bone marrow stromal cells (BMSCs). In the present study, we explored the interaction between the urokinase plasminogen activator (uPA) system and the leukemia bone marrow microenvironment (BMM). We established BMSCs-HL60 and HS-5-K562 co-culture models in direct contact mode to simulate the BMM in leukemia. In BMSCs-HL60 co-culture model, the expression levels of uPA, uPA receptor (uPAR), plasminogen activator inhibitor 1 (PAI-1) and vascular endothelial growth factor (VEGF) in BMSCs were higher than those in mono-cultured BMSCs. Matrix metalloproteinase (MMP)-9 (MMP-9) was up-regulated in co-cultured HL60 cells. In HS-5-K562 co-culture model, only uPA, PAI-1, and VEGF-A were up-regulated in HS-5 cells. The levels of the uPA protein in the co-culture supernatant were significantly higher than that of mono-cultured BMSCs or HS-5 cells. Our findings demonstrate that the co-culture stimulates the production of uPA, uPAR, PAI-1, MMP-9, and VEGF-A by BMSCs. It could further explain how the uPA system in leukemia cells is involved in the growth, development, and prognosis of leukemia.

Endokinin A/B stimulates rat gastric motility through myogenic NK1 receptors located in the fundus.

Endokinin A/B (EKA/B), the common C-terminal decapeptide in endokinins A and B, is a preferred ligand of the NK1 receptor and regulates pain and itch. The study focused on the effects of EKA/B on rat gastric motility in vivo and in vitro. Gastric emptying was measured to evaluate gastric motility in vivo. Intragastric pressure and the contraction of gastric muscle strips were measured to evaluate gastric motility in vitro. Moreover, various neural blocking agents and neurokinin receptor antagonists were applied to explore the mechanisms. TAC4 and TACR1 mRNAs were expressed throughout rat stomach. EKA/B promoted gastric emptying by intraperitoneal injection in vivo. Correspondingly, EKA/B also increased intragastric pressure in vitro. Additionally, EKA/B contracted the gastric muscle strips from the fundus but not from the corpus or antrum. Further studies revealed that the contraction induced by EKA/B on muscle strips from the fundus could be significantly reduced by NK1 receptor antagonist SR140333 but not by NK2 receptor antagonist, NK3 receptor antagonist, or the neural blocking agents used. Our results suggested that EKA/B might stimulate gastric motility mainly through the direct activation of myogenic NK1 receptors located in the fundus.

A FRET Based Two-Photon Fluorescent Probe for Visualizing Mitochondrial Thiols of Living Cells and Tissues.

Glutathione (GSH) is the main component of the mitochondrial thiol pool and plays key roles in the biological processes. Many evidences have suggested that cysteine and homocysteine also exist in mitochondria and are interrelated with GSH in biological systems. The fluctuation of the levels of mitochondrial thiols has been linked to many diseases and cells' dysfunction. Therefore, the monitoring of mitochondrial thiol status is of great significance for clinical studies. We report here a novel fluorescence resonance energy transfer based two-photon probe MT-1 for mitochondrial thiols detection. MT-1 was constructed by integrating the naphthalimide moiety (donor) and rhodamine B (accepter and targeting group) through a newly designed linker. MT-1 shows a fast response, high selectivity, and sensitivity to thiols, as well as a low limit of detection. The two-photon property of MT-1 allows the direct visualization of thiols in live cells and tissues by two-photon microscopy. MT-1 can serve as an effective tool to unravel the diverse biological functions of mitochondrial thiols in living systems.

In vitro and in vivo characterization of the bifunctional µ- and δ- opioid receptors ligand MCRT on mouse gastrointestinal motility.

BACKGROUND: Chimeric opioid MCRT was a novel multi-target ligand based on morphiceptin and PFRTic-NH2, and produced potent analgesia (ED50 = 0.03 nmol/mouse) with less upper gastrointestinal dysmotility. In this study, we sought to perform the tests to evaluate the pharmacological effects of MCRT on distal colon motility and defecation function. Moreover, opioid receptor antagonists and neuropeptide FF (NPFF) receptor antagonists were utilized to explore the mechanisms. METHODS: Isolated mouse colon bioassay and colonic bead expulsion were to characterize MCRT-induced inhibition of colonic motility in vitro and in vivo, respectively. Fecal pellet output was to evaluate the defecation function. RESULTS: (1) In vitro, MCRT increased colonic contraction via µ- and δ- opioid receptors (MOR and DOR). (2) In vivo, MCRT delayed colonic bead expulsion (ED50 = 1.1 nmol/mouse) independent of opioid and NPFF receptors. (3) In vivo, MCRT inhibited fecal number (ED50 = 1.43 nmol/mouse) and dry weight (ED50 = 1.63 nmol/mouse), which was mediated by DOR partially but not MOR. CONCLUSIONS: (1) Data indicated that MCRT was less prone to induce gastrointestinal dysmotility at analgesic doses, and provided a possibility for safer opioid analgesic. (2) Based on the mechanism explorations, we speculated on the existence of such an opioid receptor subtype or MOR/DOR heterodimer, which was involved in the central analgesia and the in vitro colonic contractions but not the central colonic dysmotility.

A single stranded fluorescent peptide probe for targeting collagen in connective tissues.

We herein report the construction of a novel single stranded fluorescent collagen mimetic peptide by introducing a bulky FAM dye in the central region rather than the N terminus. Without the need for any prior thermal or ultraviolet treatment, the peptide probe can be conveniently applied to specifically target collagen in connective tissues for fluorescence imaging.

Supraspinal inhibitory effects of chimeric peptide MCRT on gastrointestinal motility in mice.

OBJECTIVES: Chimeric peptide MCRT, based on morphiceptin and PFRTic-NH2 , was a bifunctional ligand of µ- and δ-opioid receptors (MOR-DOR) and produced potent analgesia in tail-withdrawal test. The study focused on the supraspinal effects of morphiceptin, PFRTic-NH2 and MCRT on gastrointestinal motility. Moreover, opioid receptor antagonists, naloxone (non-selective), cyprodime (MOR selective) and naltrindole (DOR selective) were utilized to explore the mechanisms. METHODS: Intracerebroventricular administration was achieved via the implanted cannula. Gastric emptying and intestinal transit were measured to evaluate gastrointestinal motility. KEY FINDINGS: (1) At supraspinal level, morphiceptin, PFRTic-NH2 and MCRT significantly decreased gastric emptying and intestinal transit; (2) MCRT at 1 nmol/mouse, far higher than its analgesic dose (ED50  = 29.8 pmol/mouse), failed to regulate the gastrointestinal motility; (3) MCRT-induced gastrointestinal dysfunction could be completely blocked by naloxone and naltrindole, but not affected by cyprodime. CONCLUSIONS: (1) Morphiceptin and PFRTic-NH2 played important roles in the regulation of gastrointestinal motility; (2) MCRT possessed higher bioactivity of pain relief than gastrointestinal regulation, suggesting its promising analgesic property; (3) MCRT-induced motility disorders were sensitive to DOR but not to MOR blockade, indicating the pain-relieving specificity of speculated MOR subtype or splice variant or MOR-DOR heterodimer.

MCRT, a chimeric peptide based on morphiceptin and PFRTic-NH2, regulates the depressor effects induced by endokinin A/B.

The interactions of the chimeric peptide MCRT (YPFPFRTic-NH2), based on morphiceptin and neuropeptide FF derivative PFRTic-NH2, on the effects of endokinin A/B (EKA/B) on mean arterial blood pressure of the urethane-anaesthetized rat have been investigated in the absence and presence of tachykinin receptor antagonists, naloxone and NO synthase inhibitors. While MCRT produced dose dependent decreases in mean arterial pressure, in its presence only a small but statistically insignificant decreases in the magnitude and the time course of the depressor effect of EKA/B (10nmol/kg) were observed. MCRT had little influence on the depressor effect of EKA/B (1 nmol/kg), but strongly potentiated that of EKA/B (100nmol/kg). The tachykinin NK1 receptor antagonist SR140333B (1mg/kg) and the NK3 antagonist SR142891 (2.79mg/kg) both reduced the hypotensive effects of EKA/B and MCRT alone and blocked those of the two peptides in combination. The NK2 antagonist GR159897 (4mg/kg) partially blocked the depressor effects of EKA/B and MCRT alone. Naloxone (2mg/kg) completely blocked the depressor effect of MCTR, but partially blocked that of EKA/B. The NO synthase inhibitor l-NAME (50mg/kg) partially blocked the depressor effects of EKA/B, MCRT, and EKA/B + MCRT. These results could help to better understand the role of tachykinin receptors, opioid receptors and neuropeptide FF receptors in cardiovascular system.

Pain regulation of endokinin A/B or endokinin C/D on chimeric peptide MCRT in mice.

The present study focused on the interactive pain regulation of endokinin A/B (EKA/B, the common C-terminal decapeptide in EKA and EKB) or endokinin C/D (EKC/D, the common C-terminal duodecapeptide in EKC and EKD) on chimeric peptide MCRT (YPFPFRTic-NH2, based on YPFP-NH2 and PFRTic-NH2) at the supraspinal level in mice. Results demonstrated that the co-injection of nanomolar EKA/B and MCRT showed moderate regulation, whereas 30 pmol EKA/B had no effect on MCRT. The combination of EKC/D and MCRT produced enhanced antinociception, which was nearly equal to the sum of the mathematical values of single EKC/D and MCRT. Mechanism studies revealed that pre-injected naloxone attenuated the combination significantly compared with the equivalent analgesic effects of EKC/D alone, suggesting that EKC/D and MCRT might act on two totally independent pathways. Moreover, based on the above results and previous reports, we made two reasonable hypotheses to explain the cocktail-induced analgesia, which may potentially pave the way to explore the respective regulatory mechanisms of EKA/B, EKC/D, and MCRT and to better understand the complicated pain regulation of NK1 and µ opioid receptors, as follows: (1) MCRT and endomorphin-1 possibly activated different µ subtypes; and (2) picomolar EKA/B might motivate the endogenous NPFF system after NK1 activation.

Tetrazine-Containing Amino Acid for Peptide Modification and Live Cell Labeling.

A novel amino acid derivative 3-(4-(1, 2, 4, 5-tetrazine-3-yl) phenyl)-2-aminopropanoic acid was synthesized in this study. The compound possessed better water-solubility and was synthesized more easily compared with the well-known and commercially available 3-(p-benzylamino)-1, 2, 4, 5-tetrazine. Tetrazine-containing amino acid showed excellent stability in biological media and might be used for cancer cell labeling. Moreover, the compound remained relatively stable in 50% TFA/DCM with little decomposition after prolonged exposure at room temperature. The compound could be utilized as phenylalanine or tyrosine analogue in peptide modification, and the tetrazine-containing peptide demonstrated more significant biological activity than that of the parent peptide. The combination of tetrazine group and amino acid offered broad development prospects of the bioorthogonal labeling and peptide synthesis.

Interaction of endokinin A/B and (Mpa(6))-γ2-MSH-6-12 in pain regulation in mice.

The present study focused on the interactive effects of (Mpa(6))-γ2-MSH-6-12 (Mpa, spinal level) and endokinin A/B (EKA/B, supraspinal level) on pain regulation in mice. EKA/B (30 pmol) only weakened 100 pmol Mpa-induced hyperalgesia at 5 min, but could enhance it during 20-30 min. However, EKA/B (100 pmol) antagonized all dose levels of Mpa significantly at 5 min and blocked them completely at 10 min. EKA/B (3 nmol) co-injected with Mpa presented marked analgesia at 5 min and enduring hyperalgesia within 20-60 min. To investigate the underlying mechanisms between Mpa and EKA/B, SR140333B and SR142801 (NK1 and NK3 receptor antagonists, respectively) were utilized. SR140333B had no influence on Mpa, while SR142801 potentiated it during 20-30 min. Whereas, SR140333B and SR142801 could block the co-administration of Mpa and EKA/B (30 pmol) separately at 5 min and 30 min. These phenomena might attribute to that these two antagonists promoted the antagonism of EKA/B (30 pmol) at the early stage, while antagonized EKA/B preferentially in the latter period. SR140333B weakened the analgesia of EKA/B (3 nmol), but produced no effect on Mpa. However, SR140333B failed to affect the co-injection of Mpa and EKA/B, which implied that EKA/B cooperated with Mpa prior to SR140333B. These results could potentially help to better understand the interaction of NK and MrgC receptors in pain regulation in mice.

The cardiovascular effects of a chimeric opioid peptide based on morphiceptin and PFRTic-NH2.

MCRT (YPFPFRTic-NH(2)) is a chimeric opioid peptide based on morphiceptin and PFRTic-NH(2). In order to assess the cardiovascular effect of MCRT, it was administered by intravenous (i.v.) injection targeting at the peripheral nervous system and by intracerebroventricular (i.c.v.) injection targeting at the central nervous system. Naloxone and L-NAME were injected before MCRT to investigate possible interactions with MCRT. Results show that administration of MCRT by i.v. or i.c.v. injection could induce bradycardia and decrease in mean arterial pressure (MAP) at a greater degree than that with morphiceptin and PFRTic-NH(2). When MCRT and NPFF were coinjected, we observed a dose-dependent weakening of these cardiovascular effects by MCRT. Because naloxone completely abolished the cardiovascular effects of MCRT, we conclude that opioid receptors are involved in regulating the MAP of MCRT regardless of modes of injection. The effect of MCRT on heart rate is completely dependent on opioid receptors when MCRT was administered by i.c.v. instead of i.v. The central nitric oxide (NO) pathway is involved in regulating blood pressure by MCRT under both modes of injection, but the peripheral NO pathway had no effect on lowering blood pressure mediated by MCRT when it was administered by i.c.v. Based on the results from different modes of injection, the regulation of heart rate by MCRT mainly involves in the central NO pathway. Lastly, we observed that the cardiovascular effects of MCRT such as bradycardia and decrease of blood pressure, were stronger than that of its parent peptides. Opioid receptors and the NO pathway are involved in the cardiovascular regulation by MCRT, and their degree of involvement differs between intravenous and intracerebroventricular injection.

Effects of endokinin A/B and endokinin C/D on the antinociception properties of hemopressin in mice.

The current study evaluated the effects of hemopressin (HP) on pain modulation by endokinin A/B (EKA/B) and endokinin C/D (EKC/D) at the supraspinal level in mice. Intracerebroventricular administration of HP (10 nmol) fully antagonized the hyperalgesia induced by EKA/B (10, 30, and 100 pmol), and induced a dose-dependent potent analgesic effect. HP at different concentrations (10 pmol, 100 pmol, and 1 nmol) showed varying effects on the analgesic effect of EKA/B (3 nmol). HP extended the duration of the analgesic effect of EKC/D (3 nmol). Moreover, HP at different concentrations (10 pmol, 5 pmol, 1 pmol, and 100 fmol) co-administered with EKC/D (30 pmol) induced significant analgesia at two different time points: 5 min and 50 min. To investigate the antinociceptive mechanism, we used SR140333B and SR142801. HP (1 pmol) potentiated the analgesic effect of SR140333B (100 pmol)+EKA/B (30 pmol) in 5-10 min, while HP (100 pmol) had no effect in the analgesia induced by SR140333B (3 nmol)+EKA/B (3 nmol). HP (1 nmol) fully inhibited the analgesic effect of SR140333B (3 nmol)+EKC/D (3 nmol) or SR142801 (3 nmol)+EKC/D (3 nmol). HP (1 pmol) weakened the analgesic effect of SR142801 (100 pmol)+EKA/B (30 pmol), but HP (100pmol) strengthened the analgesic effect of SR142801 (3 nmol)+EKA/B (3 nmol). These findings may pave the way for a new strategy on investigating the interaction between tachykinins and opioids on pain modulation.

Analgesic properties of chimeric peptide based on morphiceptin and PFRTic-amide.

A chimeric opioid peptide (MCRT, YPFPFRTic-NH(2)) was here designed and synthesized. This peptide was based on morphiceptin (YPFP-NH(2)) and a neuropeptide FF (NPFF) derivative (PFRTic-NH(2)) sharing one proline. This peptide is intended to produce potent analgesia. MCRT was found to induce analgesic activity in a dose- and time-dependent manner, as indicated by a tail flick latency test in mice to which it had been intracerebroventricularly administered (5-60 min, 0.025-2.5 nmol/kg (0.5-50 pmol per mouse), ED(50)=1.49 nmol/kg). At 2.5nmol/kg, MCRT showed significantly higher levels of analgesic activity than morphiceptin or PFR(Tic)amide at 2500 nmol/kg. Naltrindole and cyprodime were found to partially but significantly inhibit this analgesic activity, but naloxone blocked it completely. The kappa opioid receptor antagonist nor-BNI was found to slightly inhibit MCRT and morphiceptin. Pre-injection of BIBP3226 and co-administration of NPFF and MCRT showed that NPFF receptors were involved in the analgesia of MCRT. BIBP3226 was found to weaken the analgesic effects of MCRT, but BIBP3226 could not block the analgesic effects of PFR(Tic)amide. Overall, MCRT was found to have stronger analgesic activity than morphiceptin or PFR(Tic)amide when interacting with mixed µ/δ opioid receptor interactions. MCRT also showed partial interaction with NPFF receptors.

Effects of endokinin A/B, endokinin C/D, and endomorphin-1 on the regulation of mean arterial blood pressure in rats.

Endokinins are four novel human tachykinins, including endokinins A (EKA), B (EKB), C (EKC), and D (EKD). Endokinin A/B (EKA/B) is the common C-terminal decapeptide in EKA and EKB, while endokinin C/D (EKC/D) is the common C-terminal duodecapeptide in EKC and EKD. In this study, we attempted to investigate the interactions between EKA/B, EKC/D, and endomorphin-1 (EM-1) on the depressor effect at peripheral level. The effects of EKA/B produced a U-shaped curve. The maximal effect was caused by 10 nmol/kg. EKC/D and EM-1 showed a dose-dependent relationship. Co-administration of EKA/B (0.1, 1, 10 nmol/kg) with EM-1 produced effects similar to those of EKA/B alone but slightly lower. Co-injection of EKA/B (100 nmol/kg) with EM-1 caused an effect stronger than any separate injection. Co-administration of EKC/D (10 nmol/kg) with EM-1 (30 nmol/kg) caused a depressor effect, which was one of the tradeoffs of EM-1 and EKC/D. Mechanism studies showed that SR140333B could block the depressor effects of EKA/B, EKC/D, EM-1, EKA/B+EM-1, and EKC/D+EM-1; SR48968C could block EM-1, EKA/B, EKC/D, and EKC/D+EM-1 and partially block EKA/B+EM-1; SR142801 could block EM-1, EKC/D, and EKC/D+EM-1 and partially block EKA/B and EKA/B+EM-1; naloxone could block EM-1, EKC/D, and EKC/D+EM-1 and partially block EKA/B and EKA/B+EM-1. Pretreatment with NG-nitro-l-arginine methyl ester partially decreased depressor intensity and half-recovery time of EKA/B and EKC/D.

Synthesis and diuretic activities of pseudoproline-containing analogues of the insect kinin core pentapeptide.

C-2 dimethylated/unmethylated thiazolidine-4-carboxylic acid and C-2 dimethylated oxazolidine-4-carboxylic acid were introduced into the insect kinin core pentapeptide in place of Pro(3) , yielding three new analogues. NMR analysis revealed that the peptide bond of Phe(2) -pseudoproline (ΨPro)(3) is practically 100% in cis conformation in the case of dimethylated pseudoproline-containing analogues, about 50% cis for the thiazolidine-4-carboxylic acid analogue and about 33% cis for the parent Pro(3) peptide. The diuretic activities are consistent with the population of cis conformation of the Phe(2) -ΨPro(3) /Pro(3) peptide bonds, and the results confirm a cis Phe-Pro bond as bioactive conformation.

Preliminary analgesic properties of deltorphin-5-methoxytryptamine chimeric opioid peptides.

To further understand the relationship between melatonin (MT) and deltorphins (Dels) in pain modulation, two chimeric peptides (Del I-5-methoxytryptamine and Del II-5-methoxytryptamine) both containing 5-methoxytryptamine at the carboxyl-terminal of Dels mimicking MT were designed, synthesized and characterized by tail-flick assay in mice. Results showed that intracerebroventricular (i.c.v.) administration of Del I-5-methoxytryptamine (YaFDVVG-X, X is 5-methoxytryptamine, 5, 50 nmol/kg) or Del II-5-methoxytryptamine (YaFEVVG-X, X is 5-methoxytryptamine, 5, 50 nmol/kg) produced stronger analgesia than deltorphins (Del I or Del II alone), and acting even longer and stronger than cocktails containing Del I or Del II (50 nmol/kg) and MT (50 nmol/kg). Naloxone (i.p., 100 nmol/kg) could totally block the analgesic effects induced by the chimeric peptides, while luzindole (specific antagonist of melatonin receptor, i.p., 250 nmol/kg) could only partially inhibit the effects down to that induced by Dels alone. Interestingly, Del I-5-methoxytryptamine and Del II-5-methoxytryptamine act weaker with δ receptor than Dels in vitro but could induce much longer analgesia through co-activating δ opioid receptor and melatonin receptor.