Alanine scan of the opioid peptide dynorphin B amide.

To date structure-activity relationship (SAR) studies of the dynorphins (Dyn), endogenous peptides for kappa opioid receptors (KOR), have focused almost exclusively on Dyn A with minimal studies on Dyn B. While both Dyn A and Dyn B have identical N-terminal sequences, their C-terminal sequences differ, which could result in differences in pharmacological activity. We performed an alanine scan of the non-glycine residues up through residue 11 of Dyn B amide to explore the roles of these side chains in the activity of Dyn B. The analogs were synthesized by fluorenylmethyloxycarbonyl (Fmoc)-based solid phase peptide synthesis and evaluated for their opioid receptor affinities and opioid potency and efficacy at KOR. Similar to Dyn A the N-terminal Tyr1 and Phe4 residues of Dyn B amide are critical for opioid receptor affinity and KOR agonist potency. The basic residues Arg6 and Arg7 contribute to the KOR affinity and agonist potency of Dyn B amide, while Lys10 contributes to the opioid receptor affinity, but not KOR agonist potency, of this peptide. Comparison to the Ala analogs of Dyn A (1-13) suggests that the basic residues in the C-terminus of both peptides contribute to KOR binding, but differences in their relative positions may contribute to the different pharmacological profiles of Dyn A and Dyn B. The other unique C-terminal residues in Dyn B amide also appear to influence the relative affinity of this peptide for KOR versus mu and delta opioid receptors. This SAR information may be applied in the design of new Dyn B analogs that could be useful pharmacological tools.

Synthesis, biological evaluation and structural analysis of novel peripherally active morphiceptin analogs.

Morphiceptin (Tyr-Pro-Phe-Pro-NH2), a tetrapeptide amide, is a selective ligand of the µ-opioid receptor (MOR). This study reports the synthesis and biological evaluation of a series of novel morphiceptin analogs modified in positions 2 or/and 4 by introduction of 4,4-difluoroproline (F2Pro) in l or d configuration. Depending on the fluorinated amino acid configuration and its position in the sequence, new analogs behaved as selective full MOR agonists showing high, moderate, or relatively low potency. The most potent analog, Tyr-F2Pro-Phe-D-F2Pro-NH2, was also able to activate the κ-opioid receptor (KOR), although with low potency. Docking studies and the comparison of results with the high resolution crystallographic structure of a MOR-agonist complex revealed possible structure-activity relationships of this compound family.

Synthesis of the kyotorphin precursor benzoyl-L-tyrosine-L-argininamide with immobilized α-chymotrypsin in sequential batch with enzyme reactivation.

α-Chymotrypsin was immobilized in activated agarose support and the stability of the biocatalyst was assessed in three polar organic solvents, namely, ethanol, diglyme, and acetonitrile. Ethanol was the solvent in which the stability of the enzyme was higher and was then selected to perform the synthesis of the kyotorphin derivative benzoyl-tyrosine argininamide, evaluating enzyme reactivation after synthesis. Substrates for reaction were benzoyl tyrosine ethyl ester and argininamide, the reaction being performed under kinetic control. High conversion yield (85%) was obtained and the immobilized enzyme was successfully used in sequential batch reactor operation with enzyme reactivation after three batches.

Inhibition of nociceptive responses after systemic administration of amidated kyotorphin.

BACKGROUND AND PURPOSE: Kyotorphin (KTP; L-Tyr-L-Arg), an endogenous neuropeptide, is potently analgesic when delivered directly to the central nervous system. Its weak analgesic effects after systemic administration have been explained by inability to cross the blood-brain barrier (BBB) and detract from the possible clinical use of KTP as an analgesic. In this study, we aimed to increase the lipophilicity of KTP by amidation and to evaluate the analgesic efficacy of a new KTP derivative (KTP-amide - KTP-NH(2) ). EXPERIMENTAL APPROACH: We synthesized KTP-NH(2) . This peptide was given systemically to assess its ability to cross the BBB. A wide range of pain models, including acute, sustained and chronic inflammatory and neuropathic pain, were used to characterize analgesic efficacies of KTP-NH(2) . Binding to opioid receptors and toxicity were also measured. KEY RESULTS: KTP-NH(2) , unlike its precursor KTP, was lipophilic and highly analgesic following systemic administration in several acute and chronic pain models, without inducing toxic effects or affecting motor responses and blood pressure. Binding to opioid receptors was minimal. KTP-NH(2) inhibited nociceptive responses of spinal neurons. Its analgesic effects were prevented by intrathecal or i.p. administration of naloxone. CONCLUSIONS AND IMPLICATIONS: Amidation allowed KTP to show good analgesic ability after systemic delivery in acute and chronic pain models. The indirect opioid-mediated actions of KTP-NH(2) may explain why this compound retained its analgesic effects although the usual side effects of opioids were absent, which is a desired feature in next-generation pain medications.

Synthesis and activity of endomorphin-2 and morphiceptin analogues with proline surrogates in position 2.

The opioid agonists endomorphins (Tyr-Pro-Trp-Phe-NH(2); EM1 and Tyr-Pro-Phe-Phe-NH(2); EM2) and morphiceptin (Tyr-Pro-Phe-Pro-NH(2)) exhibit an extremely high selectivity for mu-opioid receptor. Here a series of novel EM2 and morphiceptin analogues containing in place of the proline at position 2 the S and R residues of beta-homologues of proline (HPro), of 2-pyrrolidinemethanesulphonic acid (HPrs) and of 3-pyrrolidinesulphonic acid (betaPrs) have been synthesized and their binding affinity and functional activity have been investigated. The highest micro-receptor affinity is shown by [(S)betaPrs(2)]EM2 analogue (6e) which represents the first example of a beta-sulphonamido analogue in the field of opioid peptides.

Synthesis and biological evaluation of novel peripherally active morphiceptin analogs.

Morphiceptin (Tyr-Pro-Phe-Pro-NH(2)), a tetrapeptide present in the enzymatic digest of bovine beta-casein, is a selective ligand of the mu-opioid receptor. In the present study, we describe the synthesis of a series of novel morphiceptin analogs modified in positions 1-3. Two of the obtained analogs, [Dmt(1), D-Ala(2), D-1-Nal(3)]morphiceptin and [Dmt(1), D-NMeAla(2), D-1-Nal(3)]morphiceptin (Dmt-2',6'-dimethyltyrosine and d-1-Nal-3-(1-naphthyl)-D-alanine)) displayed very high mu-receptor affinity, resistance to enzymatic degradation, and remarkable supraspinally mediated analgesia, as shown in the hot-plate test after intracerebroventricular but not intravenous administration, which indicated that they could not cross the blood-brain barrier. Therefore, these two analogs were further tested in vitro and in vivo towards their possible peripheral analgesic activity and inhibitory effect on gastrointestinal (GI) motility. We report that both peptides showed strong antinociceptive effect in the writhing test after intraperitoneal administration, inhibited smooth muscle contractility in vitro and GI motility in vivo. Taken together, these findings indicate that the novel morphiceptin analogs which induce peripheral, but not central antinociception, inhibit GI transit, and possess exceptional metabolic stability, may provide an interesting approach to the development of peripherally restricted agents for the treatment of GI motility disorders, such as diarrhea or diarrhea-predominant irritable bowel syndrome.

Synthesis and biological evaluation of cyclic endomorphin-2 analogs.

In our previous paper we reported synthesis and biological activity of two cyclic analogs of endomorphin-2 (EM-2): Tyr-c(Lys-Phe-Phe-Asp)-NH(2) and Tyr-c(Asp-Phe-Phe-Lys)-NH(2), achieved by making an amid bond between Lys and Asp side-chains. The first analog did not bind to the mu-opioid receptor, the affinity of the second one was very low. In the present study, we describe the synthesis of four novel cyclic analogs of similar structure, but with d-amino acids in position 2 (D-Lys or D-Asp). All new analogs displayed high affinity for the mu-opioid receptor, were much more stable than EM-2 in rat brain homogenate and showed remarkable antinociceptive activity after intracerebroventricular (i.c.v.) administration. Analgesic effect of the most potent cyclic analog, Tyr-c(D-Lys-Phe-Phe-Asp)NH(2) was much stronger and longer lasting than that of EM-2. This analog elicited analgesia also after peripheral administration and this effect was reversed by concomitant i.c.v. injection of the mu-opioid antagonist, beta-funaltrexamine, which indicated that antinociception was mediated by the mu-opioid receptor in the brain. Central action of the cyclic analog gives evidence that it was able to cross the blood-brain barrier, most likely due to the increased lipophilicity. Our results demonstrate that cyclization might be a promising strategy to enhance bioavailability of peptides and may serve a role in the development of novel endomorphin analogs with increased therapeutic potential.

[Dmt1, d-1-Nal3]morphiceptin, a novel opioid peptide analog with high analgesic activity.

The morphiceptin-derived peptide [Dmt1, d-1-Nal3]morphiceptin, labeled mu-opioid receptor (MOP) with very high affinity and selectivity in the receptor binding assays. In the mouse hot plate test, [Dmt1, d-1-Nal3]morphiceptin given intracerebroventricularly (i.c.v.) produced profound supraspinal analgesia, being approximately 100-fold more potent than the endogenous MOP receptor ligand, endomorphin-2. The antinociceptive effect of this new analog lasted up to 120min. Thus, [Dmt1, d-1-Nal3]morphiceptin is an interesting and extraordinarily potent analgesic, raising the possibility of novel approaches in the design of clinically useful drugs for pain treatment.

Type 1 diabetes attenuates the modulatory effects of endomorphins on mouse colonic motility.

Our previous studies have shown that endomorphins (EMs), endogenous ligands for mu-opioid receptor, display a significant potentiation effect on mouse colonic motility. In the present study, to assess whether diabetes alters these modulatory effects of EMs on colonic motility, we investigated the effects of EMs in type 1 diabetic mouse colon in vitro. At 4 weeks after the onset of diabetes, carbachol-induced contractions in the longitudinal muscle of distal colon were significantly reduced compared to those of non-diabetic mice. Furthermore, the contractile effects induced by EMs in the longitudinal muscle of distal colon and in the circular muscle of proximal colon were also significantly reduced by type 1 diabetes. It is noteworthy that EMs-induced longitudinal muscle contractions were not significantly affected by atropine, Nomega-nitro-l-arginine methylester (l-NAME), phentolamine, propranolol, hexamethonium, methysergide and naltrindole. On the other hand, tetrodotoxin, indomethacin, naloxone, beta-funaltrexamine, naloxonazine and nor-binaltorphimine completely abolished these effects. These mechanisms responsible for EMs-induced modulatory effects in type 1 diabetes were in good agreement with those of non-diabetes, indicating similar mechanisms in both diabetes and non-diabetes. At 8 weeks after the onset of diabetes, both carbachol- and EMs-induced longitudinal muscle contractions were similar to those of short-time (4 weeks) diabetic mice. In summary, all the results indicated that type 1 diabetes significantly attenuated the modulatory effects of EMs on the mouse colonic motility, but the mechanisms responsible for these effects were not significantly altered.

In vitro and in vivo characterization of opioid activities of endomorphins analogs with novel constrained C-terminus: evidence for the important role of proper spatial disposition of the third aromatic ring.

In the present study, the C-terminus of endomorphin (Tyr(1)-Pro(2)-Trp/Phe(3)-Phe(4)-NH(2), EMs) analogs [Xaa(4)-R]EMs, modified by substitution of a non-aromatic residue for Phe(4) and ending up with -NH-benzyl, were designed to generate an atypical conformationally constrained peptide set. We investigated the effects of these analogs on the opioid receptors affinity, guinea pig ileum (GPI) and mouse vas deferens (MVD) activity, system arterial pressure (SAP), heart rate (HR), antinociception and colonic motility. Analogs 5 ([D-V(4)-Bzl]EM1) and 10 ([D-V(4)-Bzl]EM2), which exhibit appropriate spatial orientations of the third aromatic ring, were about 3-4 times more potent than their parents both in vivo and in vitro. However, a drastic loss of activity was found in analogs 2 ([A(4)-Bzl]EM1) and 7 ([A(4)-Bzl]EM2), which possess improper spatial orientations of the third aromatic ring. Interestingly, analog 7 or 3 ([G(4)-Bzl]EM1), when injected intravenously (i.v.), produced significantly different changes in SAP from their parents. Surprisingly, analog 4 displayed relatively higher vasodepressor activity but significantly less potent colonic contractile activity than analog 5. This may be elicited by the differences in the spatial disposition of the third aromatic ring, which were verified by molecular modeling. Our results indicate that the proper spatial disposition of the third aromatic ring plays an important role in the regulation of pharmacological activities of EMs.

Membrane interactions of dynorphins.

The dynorphins are primarily endogenous ligands to the kappa-opioid receptor, but a variety of non-opioid effects have also been observed, including direct effects on membranes. The peptides are rich in Arg residues, a characteristic feature of the cell-penetrating peptides. In this investigation, we have examined the interaction of the two peptides dynorphin A and dynorphin B with model membranes. A variety of NMR methods, as well as CD and fluorescence spectroscopy, have been used to characterize the structure of the two peptides and, more importantly, the position of the peptides in phospholipid bicelles. Both peptides interact to a large extent with both zwitterionic and partly negatively charged bicelles but are only marginally structured in either solvent. Dynorphin A was found to insert its N-terminus into the bilayer of the bicelle, while dynorphin B was found to reside on the surface of the bilayer. Despite the high degree of similarity in the sequence of the two peptides, it has previously been observed that dynorphin A has membrane perturbing effects and causes leakage of calcein from large unilamellar phospholipid vesicles while dynorphin B has no such effects. Our results provide a possible explanation for the difference in membrane perturbation.

Unusual amino acids: synthesis and introduction into naturally occurring peptides and biologically active analogues.

This review covers our recent advances in the synthesis of unusual amino acids in optically pure form, and their introduction into naturally occurring peptides with specific biological properties, or into modified bioactive peptides, aiming to obtain analogues displaying enhanced performances in term of activity, bioavailability and resistance to enzymatic hydrolysis.

Synthesis and antinociceptive activity of cyclic endomorphin-2 and morphiceptin analogs.

Cyclic analogs of the opioid peptides endomorphin-2 and morphiceptin of the type Tyr-X-Phe-Phe-Y-NH2 and Tyr-X-Phe-D-Pro-Y-NH2 (X = Lys or Asp and Y = Lys or Asp), respectively, were synthesized in order to test their structure-activity relationships. Antinociceptive activity of the new analogs was assessed in the hot-plate test after intracerebroventricular administration in mice. The strong analgesic effect was observed for the analogs with Asp in position 2, while the analogs with Lys in the second position were inactive. Antinociception caused by Asp2 analogs was dose-dependent and reversed by the concomitant administration of the universal opioid antagonist naloxone and by the selective kappa antagonist, nor-BNI. However, receptor binding studies revealed poor affinity of all cyclic analogs at the mu-opioid receptor and no affinity at delta- and kappa-opioid receptors. It is most likely that the new cyclic analogs produced their antinociception by the release of dynorphin A, which subsequently acted on the kappa-opioid receptor.

Morphiceptin analogues containing a dipeptide mimetic structure: an investigation on the bioactive topology at the mu-receptor.

We describe the design, the conformational behavior, and the biological activity at the mu-opioid receptor of new morphiceptin analogues. In these analogues a recently described dipeptide mimetic structure replaces both the N- and the C-terminal Xaa-Pro dipeptide of morphiceptin. Conformational investigation on the most active analogue, compared to the parent peptide, indicates a high degree of structural tolerance within the mu-opioid receptor binding site. In fact, our results indicate that only the location and the relative orientation of the side chains of the aromatic pharmacophoric residues represent the indispensable structural features for mu-receptor binding. To reach such topological arrangement, opioid peptides can adopt different conformations and configurations. In particular, opioid peptides bearing a proline residue as spacer between the two aromatic residues can adopt, in the active state, both cis and trans configurations at the Tyr(1)-Pro(2) amide bond, each of them with the appropriate backbone and side chains orientations.

Cyclic enkephalin and dermorphin analogues containing a carbonyl bridge.

Four cyclic enkephalin analogues and four cyclic dermorphin analogues have been synthesized. Cyclization of linear peptides containing basic amino acid residues of various side chain length in position 2 and 5 (enkephalin analogues) or 2 and 4 (dermorphin analogues) was achieved by treatment with bis-(4-nitrophenyl) carbonate to form a urea unit. The peptides were tested in the guinea-pig ileum (GPI) and mouse vas deferens (MVD) assays. Diverse activity was observed, depending on the size of the ring and the location of the urea unit. The conformation of two dermorphin analogues has been studied: one of high activity (IC(50) = 4.15 nM in the GPI assay) and a second of low activity (IC(50) = 6700 nM in the GPI assay). The conformational space of these peptides was examined using the EDMC method. Using data from the NMR spectra, each peptide was described as an ensemble of conformers. Biological activity was discussed in light of the structural data.

Characterization of antinociceptive activity of novel endomorphin-2 and morphiceptin analogs modified in the third position.

In the present study we investigated and compared the in vivo analgesia of centrally administered endomorphin-2 and morphiceptin, and their analogs modified in position 3. Two series of analogs were synthesized by introducing unnatural aromatic amino acids in the D configuration: 3-(1-naphthyl)-D-alanine (D-1-Nal), 3-(2-naphthyl)-D-alanine (D-2-Nal), 3-(4-chlorophenyl)-D-alanine (D-ClPhe), 3-(3,4-dichlorophenyl)-D-alanine (D-Cl2Phe). Antinociceptive activity of endomorphin-2, morphiceptin, and their analogs was compared in the mouse hot-plate test, performed after i.c.v. administration of the peptides at a dose of 10 microg/animal. The best results were obtained for two morphiceptin analogs, [D-Phe3]morphiceptin and [D-1-Nal3]morphiceptin, which showed greatly improved analgesic activity, as compared to morphiceptin. In the endomorphin-2 series none of the modifications produced analogs more potent than the parent compound, but [D-1-Nal3]endomorphin-2 was the best analog. Antinociception induced by endomorphin-2 was reversed by concomitant i.c.v. administration of [D-Phe3]endomorphin-2, [D-2-Nal3]endomorphin-2, and [D-2-Nal3]morphiceptin, indicating that these analogs were weak mu-opioid antagonists.

Synthesis and electrophysiological characterization of cyclic morphiceptin analogues.

A challenge in opioid peptide chemistry and pharmacology is the possibility to develop novel peptides with peripheral selectivity. An enzymatically stable opioid peptide could involve an antidiarrheal effect. For this reason, we constrained the highly selective and potent tetrapeptide morphiceptin with a 6-atom bridge, resulting in a cyclic amide and an ester analogue, 2 and 3, respectively. Taking advantage of the functional coupling of the opioid receptor with the heteromultimeric G-protein-coupled inwardly rectifying K+ (GIRK1/GIRK2) channel, either the wild-type mu-, kappa-, delta- or a mutated mu-opioid receptor (hMORS329A) was functionally co-expressed with GIRK1/GIRK2 channels and a regulator of G-protein signaling (RGS4) in Xenopus laevis oocytes. The two-microelectrode voltage clamp technique was used to measure the opioid receptor activated GIRK1/GIRK2 channel responses. Both cyclic analogues were equally potent via the wild-type mu-opioid receptor hMORwt (EC(50) value 976.5 +/- 41.7 for 2 and 1017.7 +/- 60.7 for 3), while the EC(50) value for Tyr-Pro-Phe-D-Pro-NH(2) measured 59.3 +/- 4.8 nM. These three agonists displayed a four to five times decreased potency via hMORS329A as compared to the wild type. Interestingly, no effect on kappa- and delta-opioid receptors was observed. The intramolecular bridge created by cyclization of morphiceptin prevents dipeptidyl peptidase IV from interacting with these analogues. We conclude that constraining morphiceptin with a 6-atom bridge resulted in enzymatically stable peptidomimetics that are exclusively active on mu-opioid receptors. These analogues provide an interesting template in the promising approach for the design of potential antidiarrheal agents.

Synthesis of novel morphiceptin analogues modified in position 3 and their binding to mu-opioid receptors in experimental mammary adenocarcinoma.

Binding of the (125)I-labeled mu-opioid receptor selective ligands, morphiceptin (Tyr-Pro-Phe-Pro-NH(2)) and [D-Phe(3)]morphiceptin, to membranes isolated from experimental mouse mammary adenocarcinoma was examined in vitro using a cross-linking assay followed by a Western blot technique. The radioactive complex had a molecular weight of about 65 kDa and was detectable by anti-mu-opioid receptor antibody, indicating the presence of mu-opioid receptors in tumor membranes. A series of new morphiceptin analogues, modified at the pharmacophoric position 3, was synthesized in order to find the correlation between the lipophilicity, electronic and steric properties of the amino acid in this position and the in vitro affinity of new analogues for mu-opioid receptors on mouse brain and tumor membranes. In in vivo studies the uptake of (131)I-labeled analogues by experimental mammary adenocarcinoma was estimated. The highest affinity for mu-opioid receptors in both, in vitro and in vivo experiments was observed for [D-Phe(3)]morphiceptin and [D-ClPhe(3)]-morphiceptin.

Bioactive pseudopeptidic analogues and cyclostereoisomers of osteogenic growth peptide C-terminal pentapeptide, OGP(10-14).

The osteogenic growth peptide (OGP) is a key factor in the mechanism of the systemic osteogenic response to local bone marrow injury. When administered in vivo, OGP stimulates osteogenesis and hematopoiesis. The C-terminal pentapeptide OGP(10-14) is the minimal amino acid sequence that retains the full OGP-like activity. Apparently, it is also the physiologic active form of OGP. Residues Tyr(10), Phe(12), Gly(13), and Gly(14) of OGP are essential for the OGP(10-14) activity. The present study explored the functional role of the peptide bonds, carboxyl and amino terminal groups, and conformational freedom in OGP(10-14). Transformations replacing the peptide bonds with surrogates such as Psi(CH(2)NH), Psi(CONMe), and Psi(CH(2)CH(2)) demonstrated that amide bonds do not contribute significantly to OGP(10-14) bioactivity. End-to-end cyclization yielded the fully bioactive cyclic pentapeptide c(Tyr-Gly-Phe-Gly-Gly). The retroinverso analogue c(Gly-Gly-phe-Gly-tyr), a cyclostereoisomer of c(Tyr-Gly-Phe-Gly-Gly), is at least as potent as the parent cyclic pentapeptide. The unique structure-activity relations revealed in this study suggest that the spatial presentation of the Tyr and Phe side chains has a major role in the productive interaction of OGP(10-14) and its truncated and conformationally constrained analogues with their cognate cellular target.

Pseudoproline-containing analogues of morphiceptin and endomorphin-2: evidence for a cis Tyr-Pro amide bond in the bioactive conformation.

Analogues of the opioid peptides [D-Phe(3)]morphiceptin (H-Tyr-Pro-D-Phe-Pro-NH(2)) and endomorphin-2 (H-Tyr-Pro-Phe-Phe-NH(2)) containing the pseudoproline (Psi Pro) (4R)-thiazolidine-4-carboxylic acid (Cys[Psi(R1,R2)pro]) or (4S)-oxazolidine-4-carboxylic acid (Ser[Psi(R1,R2)pro]) in place of Pro(2) were synthesized. The pseudoproline ring in these compounds was either unsubstituted (R(1), R(2) = H) or dimethylated (R(1), R(2) = CH(3)) at the 2-C position. 2-C-dimethylated pseudoprolines are known to be quantitative or nearly quantitative inducers of the cis conformation around the Xaa(i-1)-Xaa(i)[Psi(CH(3),CH)(3)pro)] imide bond. All dihydropseudoproline-containing analogues (R(1), R(2) = H) showed good mu opioid agonist potency in the guinea pig ileum (GPI) assay, high mu receptor binding affinity in the rat brain membrane binding assay, and, like their parent peptides, excellent mu receptor binding selectivity. (1)H NMR spectroscopic analysis of the Cys[Psi(H,H)pro](2)- and Ser[Psi(H,H)pro](2)-containing analogues in DMSO-d(6) revealed that they existed in a conformational equilibrium around the Tyr-Xaa[Psi(H,H)pro] peptide bond with cis/trans ratios of 40:60 and 45:55, respectively. The dimethylated thiazolidine- and oxazolidine-containing [D-Phe(3)]morphiceptin- and endomorphin-2 analogues (R(1), R(2) = CH(3)) all retained full mu agonist potency in the GPI assay and displayed mu receptor binding affinities in the nanomolar range and high mu receptor selectivity. As expected, no conformers of the latter analogues with a trans conformation around the Tyr-Xaa[Psi(CH(3),CH(3)pro)] imide bond were detected by (1)H NMR spectral analysis, indicating that in these compounds the cis conformation is highly predominant (>98%). These results represent the most direct evidence obtained so far to indicate that morphiceptin and endomorphin-2 have the cis conformation around the Tyr-Pro peptide bond in their bioactive conformations.