Analgesic, receptor binding, and peripheral opioid activities of synthetic dermorphin-dynorphin hybrid peptides

The effects of substituting the enkephalin moiety of dynorphin with the dermorphin sequence were studied on the receptor preference, analgesic, and peripheral opioid potencies by using synthetic dermorphin-dynorphin hybrid peptides as the probe. Replacement of the enkephalin moiety of dynorphin with the dermorphin or dermorphin1-5 sequences caused a remarkable increase in analgesic potency, and a 3-6 fold increase in potency of binding against [3H]-dihydromorphine. The potency of receptor binding against [3H]-EKC was also increased by incorporation of the whole dermorphin sequence into the dynorphin molecule. In the presence of NaCl (100 mM), the effect of enhancing binding against [3H]-EKC due to dermorphin substitution disappeared, suggesting the contribution of opioid mu-receptor. Peripheral opioid activities assayed by various smooth muscle preparations showed that dermorphin incorporation caused a decreased in the potency of inhibition of the contractions of the guinea pig ileum and the rabbit vas deferens, no change in potency on the mouse vas deferens, and a marked increase in the inhibition of the rat vas deferens. Among the peripheral opioid activities only that assayed with the rat vas deferens appears to correlate approximately with the analgesic and the receptor binding activities. Judging from the relative potencies obtained from all assays, it is evident that the N-terminal dermorphin moiety, but not the C-terminal dynorphin fragment, dominates the opioid activity and receptor preference of the hybrid peptide.     

Structural requirements for dermorphin opioid receptor binding

Structural features influencing binding activity of dermorphin to opioid receptors have been investigated in the rat brain through the synthesis and evaluation of binding affinity of a series of synthetic dermorphin analogs. Tritiated dermorphin was used as primary ligand. The single population of high affinity dermorphin binding sites present in the rat brain is clearly of an opioid nature since bound radiolabeled dermorphin was fully displaced with high affinity either by morphine or naloxone. Displacement of tritiated dermorphin by all alkaloid opiates or dermorphin related peptides tested was monophasic, consistent with simple competitive inhibition at a single population of binding sites. Dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) was the most potent competitor in all experiments. The D-configuration of the amino acid residue in position 2 was found to be of crucial importance for binding. Replacement of D-Ala2 with L-Ala led to a deleterious effect, this analog being 1/5000th as potent as dermorphin in displacing bound tritiated dermorphin from its receptor. Shorter dermorphin homologs, dermorphin-(1-4)-NH2 and dermorphin-(1-3)-NH2, were found to be 20 and 40-fold less potent, respectively, than dermorphin. The C-terminal carboxamide function is of significant importance for manifestation of the full intrinsic binding potency of dermorphin. Deamidated dermorphin had 1/5th the potency of the parent peptide. This suggests that while the whole dermorphin sequence is required for the expression of the full intrinsic binding activity of the molecule, the N-terminal tripeptide is a key structure as it contains the features which allow receptor recognition.     

Structure-activity studies of dermorphin. The role of side chains of amino acid residues on the biological activity of dermorphin

Seventeen analogues of dermorphin were synthesized and bio-assayed to determine the influence of side chains of the individual amino acid residues forming the sequence of dermorphin on the biological activity of this opioid peptide. Syntheses were carried out using solid-phase procedure, and the analogues obtained were purified by gel filtration on Sephadex G-10. Biological activities determined in guinea pig ileum (GPI) and mouse vas deferens (MVD) tests showed that the N-terminal tetrapeptide is responsible for the activity of dermorphin. Substitutions in the C-terminal fragment, particularly in position 5, for other amino acid residues results in substantial differentiation towards mu and delta receptors.     

Dermorphin tetrapeptide analogs as potent and long-lasting analgesics with pharmacological profiles distinct from morphine

Dermorphin (Tyr-d-Ala-Phe-Gly-Tyr-Pro-Ser-NH₂) is a heptapeptide isolated from amphibian skin. With a very high affinity and selectivity for μ-opioid receptors, dermorphin shows an extremely potent antinociceptive effect. The structure-activity relationship studies of dermorphin analogs clearly suggest that the N-terminal tetrapeptide is the minimal sequence for agonistic activity at μ-opioid receptors, and that the replacement of the d-Ala² residue with d-Arg² makes the tetrapeptides resistant to enzymatic metabolism. At present, only a handful of dermorphin N-terminal tetrapeptide analogs containing d-Arg² have been developed. The analogs show potent antinociceptive activity that is greater than that of morphine with various injection routes, and retain high affinity and selectivity for μ-opioid receptors. Interestingly, some analogs show pharmacological profiles that are distinct from the traditional μ-opioid receptor agonists morphine and [d-Ala²,NMePhe⁴,Gly-ol⁵]enkephalin (DAMGO). These analogs stimulate the release of dynorphins through the activation of μ-opioid receptors. The activation of κ-opioid receptors by dynorphins is suggested to reduce the side effects of μ-opioid receptor agonists, e.g., dependence or antinociceptive tolerance. The dermorphin N-terminal tetrapeptide analogs containing d-Arg² may provide a new target molecule for developing novel analgesics that have fewer side effects.     

Reversed-phase HPLC study on the in vitro enzymic degradation of dermorphin

A high-performance liquid chromatographic (HPLC) method for the separation of the opioid heptapeptide dermorphin and related fragments has been developed. The chromatographic system was applied in the study of the kinetics of degradation of dermorphin (Der) in various tissues. Der was found to be extremely resistant to human and rat plasma (T 1/2 greater than 180 min). Upon incubation with homogenates of rat brains and kidneys, Der was cleaved with a half-life of 20.8 +/- 2.2 min and 2.4 +/- 0.3 min respectively. The catabolite formed was identified, in both tissues, as the N-terminal tetrapeptide H-Tyr-D-Ala-Phe-Gly-OH. The stability to rat kidney and brain of the N-terminal hexa- and pentapeptides and of the [4 psi 5, NHCO] Der analogue was also investigated. The nature of the enzyme systems involved in the in vitro degradations is discussed.     

Prolactin releasing and luteinizing hormone inhibiting activity of dermorphin shorter homologues in the rat

Dermorphin, a heptapeptide isolated from the skin of the frogs Phillomedusa sauvagei and Phillomedusa rhodei, is endowed with potent peripheral and central opioid-like activity. Intracerebroventricular (icv) injection of dermorphin (31.2, 62.5 and 125 pmol/100g) induced in ovariectomized (OVX) rats dose related rises and decreases in prolactin (PRL) and luteinizing hormone (LH) levels, respectively. The aim of this work was to evaluate the same endocrine responses after administration of shorter peptide amide homologues, related to the N-terminal sequence of dermorphin. These compounds retain a substantial analgesic activity although the latter decreases with the decrease in the number of amino acid residues. Icv administration of the hexapeptide homologue (dermorphin 1-6 amide) to OVX rats did not induce any PRL rise or LH inhibition, even at the high dose of 250 pmol/100g. The pentapeptide (dermorphin 1-5 amide), instead, increased PRL and decreased LH secretion, although the effect was significant only at the dose of 250 pmol/100g. Administration of the tetrapeptide (dermorphin 1-4 amide) induced a significant PRL rise and LH inhibition at both the doses of 125 and 250 pmol/100g. The tetrapeptide was the smallest fragment of the dermorphin moiety which caused endocrine responses while the tripeptide (dermorphin 1-3 amide) was completely ineffective in this context. These data indicate that a complete dissociation exists between the behavioral and endocrine effects of the dermorphin homologues examined. In fact, shorter dermorphins whose analgesic potency was directly related to the number of amino acids, exhibited an opposite pattern in evoking endocrine effects.     

Synthesis and biological activity of carboxyl terminally extended dermorphins

Dermorphinoyl(DMR)-glycine, DMR-sarcosine and DMR-glycyl-arginine have been prepared in order to examine the effect of C-terminal extension of dermorphin (H-Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) on opioid activity. On GPI preparation the addition of Gly, Sar, or Gly-Arg to the carboxyl terminus of dermorphinoic acid was detrimental to mu activity: dermorphinoyl-derivatives, in fact, retain only 5-20% of dermorphin potency. Following intracerebroventricular administration (tail-flick test), whereas the analgesic activities of compounds showed the trend dermorphin greater than DMR-Sar greater than DMR-Gly-Arg greater than DMR-Gly greater than morphine, the nonapeptide displayed highest activity after subcutaneous injection in mice: DMR-Gly-Arg was 2.5 and 10 times more potent than dermorphin and morphine, respectively.     

Dermorphin: synthesis of analogs and structuro-functional relations

The review analyzes structure-activity relations among dermorphin analogues. Dermorphin (Tyr-D-Ala-Phe-Gly-Tyr-Pro-Ser-NH2) is one of natural opioid peptides having a unique structure and exerting a very potent and prolonged antinociceptive effect. Methods of dermorphin synthesis are summarized together with data on more than 300 dermorphin-like peptides: the physico-chemical characteristics and data on opioid tests in vitro and in vivo are discussed. Based on these studies, conclusions have been drawn on the functional role of each amino acid residue in the dermorphin molecule and on modifications leading to analogues with high and differential opioid activity.     

Functional and structural characterization of apidaecin and its N-terminal and C-terminal fragments.

Two aspects were studied to elucidate the functional and structural characterization of apidaecin and its N-terminal and C-terminal fragments: (i) Functions of the N-terminal and C-terminal fragments of apidaecin were first studied by measuring their antibacterial activity, their ability to enter Escherichia coli cells and their effects on the activities of beta-galactosidase and alkaline phosphatase. The results indicate that neither the N-terminal nor the C-terminal of apidaecin contains intracellular delivery unit or active segment. (ii) The effect of apidaecin on the ATPase activity of DnaK, and the interactions of apidaecin with E.coli lidless DnaK and DnaK D-E helix were studied. Results showed that apidaecin could interact with the E.coli lidless DnaK protein and stimulate its ATPase activity, but not with E.coli DnaK D-E helix. This indicated that the antimicrobial activity of apidaecin may be shown by stimulating the ATPase activity of DnaK by binding to its conventional substrate-binding site, to decrease its cellular concentration of DnaK by competing with natural substrates and inhibit the enzymes' activities of E. coli cells. It is the first study to suggest that the apidaecin-binding site of DnaK is the conventional substrate binging site.     

The potential-dependent action of the opioid peptide dermorphin]

Dermorphin action was studied on cross-section strip of frog stomach muscle by a mechanographic recorder. The results show that dermorphin (10(-5)-10(-8) M) blocks acetylcholine effects, spontaneous activity and muscle contractions induced by direct electrical stimulation. All the above effects are hardly reversible. Dermorphin fails to block spontaneous and evoked activities if it is injected into the incubated medium during K(+)-depolarization (KCI--100 mM) of the muscle. Thus, dermorphin has voltage-dependent action. The discussion deals with dermorphin action on voltage-dependent Ca(2+)-channels of muscle cell membrane.     

Structure-activity relationships of atrial natriuretic factor (ANF). II. Effect of chain-length modifications on vascular reactivity

The effect of the length of ANF peptides on the inhibition of the norepinephrine-induced contraction was studied. Starting from the 26 residues ANF (Arg101-Tyr126), shorter N- and/or C-terminal fragments were produced, either by N-terminal chemical cleavage or C-terminal enzymatic digestion of ANF or both respectively. The N-terminal removal of Arg101 did not modify the inhibitory response. Further N-terminal truncation up to des-Arg101-Arg102-Ser103-Ser104 ANF still produced a marked inhibitory effect on norepinephrine. In contrast C-terminal cleavage had a much more pronounced effect. Since des-Tyr126 ANF, des-Arg125-Tyr126 ANF and des-Phe124-Arg125-Tyr126 ANF exhibit much lower activities than the parent ANF. Finally, when the 5 residues C-terminal to Cys121 are removed, the resulting molecule is almost inactive. These data indicate that the C-terminal segment of ANF may modulate the binding of ANF to its receptor(s). Relatively, the N-terminal region seems to be much less important.     

The domain organization of streptokinase: nuclear magnetic resonance, circular dichroism, and functional characterization of proteolytic fragments.

Streptococcus equisimilis streptokinase (SK) is a bacterial protein of unknown tertiary structure and domain organization that is used extensively to treat acute myocardial infarction following coronary thrombosis. Six fragments of SK were generated by limited proteolysis with chymotrypsin and purified. NMR and CD experiments have shown that the secondary and tertiary structure present in the native molecule is preserved within all fragments, except the N-terminal fragment SK7. NMR spectra demonstrate the presence in SK of three structurally autonomous domains and a less structured C-terminal "tail." Cleavage within the N-terminal domain generates an N-terminal fragment, SK7, which remains noncovalently associated with the remainder of the molecule; in isolation, SK7 adopts an unfolded conformation. The abilities of these fragments to induce active site formation within human plasminogen upon formation of their heterodimeric complex were assayed. The lowest mass SK fragment exhibiting Plg-dependent activator activity was shown to be SK27 (mass 27,000, residues 147-380), which contains both central and C-terminal domains, although this activity was reduced approximately 6,000-fold relative to that of full-length SK. The activity of a 36,000 mass fragment, SK36 (residues 64-380), which differs from SK27 in possessing a portion of the N-terminal domain, was reduced to 0.1-1.0% of that of SK. Other fragments (masses 7,000, 11,000, 16,000, 17,000, 25,000, and 26,000), representing either single domains or single domains extended by portions of other domains, were inactive. However, SK7 (residues 1-63), at a 100-fold molar excess concentration, greatly potentiated the activities of SK27 and SK36, by up to 50- and > 130-fold, respectively. These findings demonstrate that all of SK's three domains are essential for native-like SK activity. The central and C-terminal domains mediate plasminogen-binding and active site-generating functions, whereas the N-terminal domain mediates an activity-potentiating function.     

Effect of Structural Changes of Pro6 in Dermorphin Molecule on Its Antinociceptive Activity

We studied effect of dermorphin (H-Tyr-DAla-Phe-Gly-Tyr-Pro-Ser-NH₂) and its analogs with modified amino acid residue proline in position 6, H-Tyr-DAla-Phe-Gly-Tyr-[DPro]-Ser-NH₂, H-Tyr-DAla-Phe-Gly-Tyr-[dehydro-Pro]-Ser-NH₂, and H-Tyr-DAla-Phe-Gly-Tyr-[D-dehydro-Pro]-Ser-NH₂, on nociception in the tail-flick and hot plate tests after intraperitoneal injection. Replacement of LPro with the stereoisomer DPro as well as Pro dehydration (LdHPro) was shown to increase antinociceptive activity. Replacement of LdHPro with DdHPro cancelled the activity in the tail-flick test. All three dermorphin analogs retained antinociceptive activity in the hot plate test; however, the effect of dermorphin was more pronounced.     

Ureido group containing cyclic dermorphin(1-7) analogues: synthesis, biology and conformation.

Six cyclic peptides related to dermorphin(1-7) have been synthesized. The synthesis of linear peptides containing diamino acid residues in positions 2 and 4 was carried out on a 4-methylbenzhydrylamine resin, and cyclization 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 opioid agonist activities were observed, depending on the size of the ring. The results were compared with those obtained earlier for 1-4 dermorphin analogues. The conformations of all six dermorphin analogues were studied. The conformational space of the peptides was examined using the electrostatically driven Monte Carlo method. On the basis of NMR data, an ensemble of conformations was obtained for each peptide. The opioid activity profiles of the compounds are discussed in the light of the structural data.     

Comparative analysis of analgesic activities of dermorphin, [DPro<Superscript>6</Superscript>]-dermorphin,and their C-terminal tripeptides

Analgesic activities of dermorphin (DM), [DPro⁶]-DM, and their C-terminal tripeptides were comparatively studied. Analgesic activity was evaluated in tail flick, hot plate, tail pinch, formalin, and acetic acid writhing tests describing different levels of organization of pain sensitivity. Intraperitoneal administration of the peptides decreased the pain threshold in all these tests. The C-terminal tripeptides DM_5–7 and [DPro⁶]-DM_5–7 demonstrated analgesics activity comparable or sometimes higher than that of the full-length molecules. The effect of DM, [DPro⁶]-DM, and C-terminals fragments DM_5–7 and [DPro⁶]-DM_5–7 decreased after co-administration with naloxone, which points to the opioid nature of analgesic activity of the peptides.     

Proton magnetic resonance studies on dermorphin and its peptide fragments

Dermorphin (Tyr? D-Ala? Phe? Gly? Tyr? Pro? Ser? NH₂), a potent natural peptide opioid, its synthetic L-Ala² analog, and all the N fragments from the tripeptide (Tyr? D -Ala? Phe? NH₂) to the parent hexapeptide amide were characterized for the first time by means of proton nmr spectroscopy at 11.74 T. Assignments of most protons of dermorphin were facilitated by the study of the N-terminal fragments. Comparison of spectroscopic parameters with relative pharmacological activity is proposed as a possible means of studying flexible agonists in solution.     

N-terminal portion of motilin determines its biological activity.

This study aimed to identify the portion of the 22 amino acid sequence of motilin responsible for the biological activity of the peptide. The contraction of rabbit duodenal muscle in vitro was measured when exposed to synthetic fragments of motilin corresponding to various sequences of the C- or N-terminal portions of the molecule. Fragments 2-22 or 3-22 (where the initial amino acids of the N-terminal ending were removed) were more than 1000 times less potent than the native molecule 1-22. Fragment 1-9 (where the last 13 amino acids located at the C-terminal side of motilin were removed) was devoid of any contractile capacity, while synthetic fragments whose C-terminal structure extended beyond the 1-9 motilin sequence maintained almost complete biological activity. N-terminal amino acid sequence 1-9 is therefore an essential determinant of the contractile activity of motilin.     

Conformation-activity relations of dermorphin and its pentapeptide analogs

Low-energy peptide backbone structures of dermorphin (DM), amide of its N-terminal pentapeptide (DM 1-5) and DM 1-5 analogues with substitutions of Gly4 for Leu, D-Gln, Aal or Tal were determined by energy calculations. The above analogues were shown to possess different affinities toward opiate receptors of mu-type. The comparison of low-energy backbone structures of DM, DM 1-5 and its analogues resulted in development of the dermorphin "biologically active" conformation being characteristic of its binding with mu-type receptors. The specific binding of dermorphin to this receptor apparently depends on the conformation of the whole N-terminal pentapeptide.     

N-terminal tetrapeptide of dermorphin and D-Arg-substituted tetrapeptides: inactivation process of the antinociceptive activity by peptidase

Degradation products of the N-terminal tetrapeptide of dermorphin, H-Tyr-D-Ala-Phe-Gly-OH (ALPG) and D-Arg2-substituted tetrapeptide analogs of dermorphin, H-Tyr-D-Arg-Phe-Gly-OH (ARPG), H-Tyr-D-Arg-Phe-Gly-NH2 (TDAPG-NH2) and H-Tyr-D-Arg-Phe-beta-Ala-OH (TDAPA) by enkephalin degrading enzymes were studied by using reversed-phase high-performance liquid chromatography. After 5 and 25 hr incubations of the peptides with solubilized enzymes of mouse brain or spinal cord, liberation of the appreciable Tyr1 residue was observed in ALPG but not in ARPG, TDAPG-NH2 and TDAPA. When ARPG and TDAPG-NH2 were incubated with enzymes for 25 hr, a main degradation product was the N-terminal tripeptide produced from the hydrolysis of Phe3-Gly4 bond. Conversely, TDAPA did not produce the N-terminal tripeptide after 25 hr incubation with enzymes. In the enzyme assay, Tyr1-D-Arg2 bond of ARPG, TDAPG-NH2 and TDAPA was more stable than that of ALPG to the cleavage by aminopeptidase M (AP-M). Phe3-Gly4 bond of ALPG, ARPG and TDAPG-NH2 were easily hydrolyzed by carboxypeptidase Y (CP-Y) within 3 hr incubation, whereas the hydrolysis of Phe3-beta-Ala4 bond of TDAPA by CP-Y was not observed after 3 hr incubation. The present results and previous behavioural data suggest that a potent and prolonged antinociceptive activity of the D-Arg-substituted tetrapeptides is mainly attributed to the stability of Tyr1-D-Arg2 bond against aminopeptidase of peptidases.