Erika Marzola

Structure-Activity Studies on Neuropeptide S IDENTIFICATION OF THE AMINO ACID RESIDUES CRUCIAL FOR RECEPTOR ACTIVATION

Neuropeptide S (NPS) has been recently recognized as the endogenous ligand for the previous orphan G-protein-coupled receptor GPR154, now referred to as the NPS receptor (NPSR). The NPS-NPSR receptor system regulates important biological functions such as sleeping/wakening, locomotion, anxiety, and food intake. To collect information on the mechanisms of interaction between NPS and its receptor, a classical structure-activity relationship study was performed. Human (h) NPS derivatives obtained by Ala and d-scan and N- and C-terminal truncation were assessed for their ability to stimulate calcium release in HEK293 cells expressing the human recombinant NPSR. The results of this study indicate that (i) the effect of hNPS is mimicked by the fragment hNPS-(1–10); (ii) Phe2, Arg3, and Asn4 are crucial for biological activity; (iii) the sequence Thr8-Gly9-Met10 is important for receptor activation, although with non-stringent chemical requirements; and (iv) the sequence Val6-Gly7 acts as a hinge region between the two above-mentioned domains. However, the stimulatory effect of hNPS given intracerebroventricularly on mouse locomotor activity was not fully mimicked by hNPS-(1–10), suggesting that the C-terminal region of the peptide maintains importance for in vivo activity. In conclusion, this study identified the amino acid residues of this peptide most important for receptor activation.

In Vitro and in Vivo Pharmacological Characterization of the Neuropeptide S Receptor Antagonist [d-Cys(tBu)5]Neuropeptide S

Neuropeptide S (NPS) was identified as the endogenous ligand of an orphan receptor now referred to as the NPS receptor (NPSR). In the frame of a structure-activity study performed on NPS Gly5, the NPSR ligand [d-Cys(tBu)5]NPS was identified. [d-Cys(tBu)5]NPS up to 100 μM did not stimulate calcium mobilization in human embryonic kidney (HEK) 293 cells stably expressing the mouse NPSR; however, in a concentration-dependent manner, the peptide inhibited the stimulatory effects elicited by 10 and 100 nM NPS (pKB, 6.62). In Schild analysis experiments [d-Cys(tBu)5]NPS (0.1–100 μM) produced a concentration-dependent and parallel rightward shift of the concentration-response curve to NPS, showing a pA2 value of 6.44. Ten micromolar [d-Cys(tBu)5]NPS did not affect signaling at seven NPSR unrelated G-protein-coupled receptors. In the mouse righting reflex (RR) recovery test, NPS given at 0.1 nmol i.c.v. reduced the percentage of animals losing the RR in response to 15 mg/kg diazepam and their sleeping time. [d-Cys(tBu)5]NPS (1–10 nmol) was inactive per se but dose-dependently antagonized the arousal-promoting action of NPS. Finally, NPSR-deficient mice were similarly sensitive to the hypnotic effects of diazepam as their wild-type littermates. However, the arousal-promoting action of 1 nmol NPS could be detected in wild-type but not in mutant mice. In conclusion, [d-Cys(tBu)5]NPS behaves both in vitro and in vivo as a pure and selective NPSR antagonist but with moderate potency. Moreover, using this tool together with receptor knockout mice studies, we demonstrated that the arousal-promoting action of NPS is because of the selective activation of the NPSR protein.

Synthesis and biological activity of human neuropeptide S analogues modified in position 5: identification of potent and pure neuropeptide S receptor antagonists.

Neuropeptide S (NPS), the endogenous ligand of a previously orphan receptor now named NPSR, regulates various biological functions in the brain, including arousal, locomotion, anxiety, and food intake. Here we report on a focused structure-activity study of Gly5, which has been replaced with L and D amino acids. Fifteen NPS related peptides were synthesized and pharmacologically tested for intracellular calcium mobilization using HEK293 cells stably expressing the mouse NPSR. The results of this study demonstrated that peptide potency is inversely related to the side chain size, while peptide efficacy strongly depends on the relative L and D configuration, with the L amino acids favoring agonist while D amino acids display antagonist pharmacological activity. [D-Val5]NPS behaved as NPSR pure antagonist in HEK293(mNPSR) cells showing the highest potency (pK(B) 7.56) among this series of peptides. The antagonist action of [D-Val5]NPS was confirmed in vivo in mice, where the peptide at a dose of 10 nmol completely blocked the stimulatory effect of 0.1 nmol NPS on locomotor activity.

In vitro and in vivo pharmacological characterization of the novel UT receptor ligand [Pen5,DTrp7,Dab8]urotensin II(4–11) (UFP‐803)

The novel urotensin‐II (U‐II) receptor (UT) ligand, [Pen5,DTrp7,Dab8]U‐II(4–11) (UFP‐803), was pharmacologically evaluated and compared with urantide in in vitro and in vivo assays. In the rat isolated aorta, UFP‐803 was inactive alone but, concentration dependently, displaced the contractile response to U‐II to the right, revealing a competitive type of antagonism and a pA2 value of 7.46. In the FLIPR [Ca2+]i assay, performed at room temperature in HEK293hUT and HEK293rUT cells, U‐II increased [Ca2+]i with pEC50 values of 8.11 and 8.48. Urantide and UFP‐803 were inactive as agonists, but antagonized the actions of U‐II by reducing, in a concentration‐dependent manner, the agonist maximal effects with apparent pKB values in the range of 8.45–9.05. In a separate series of experiments performed at 37°C using a cuvette‐based [Ca2+]i assay and CHOhUT cells, urantide mimicked the [Ca2+]i stimulatory effect of U‐II with an intrinsic activity (α) of 0.80, while UFP‐803 displayed a small (α=0.21) but consistent residual agonist activity. When the same experiments were repeated at 22°C (a temperature similar to that in FLIPR experiments), urantide displayed a very small intrinsic activity (α=0.11) and UFP‐803 was completely inactive as an agonist. In vivo in mice, UFP‐803 (10 nmol kg−1) antagonized U‐II (1 nmol kg−1)‐induced increase in plasma extravasation in various vascular beds, while being inactive alone. In conclusion, UFP‐803 is a potent UT receptor ligand which displays competitive/noncompetitive antagonist behavior depending on the assay. While UFP‐803 is less potent than urantide, it displayed reduced residual agonist activity and as such may be a useful pharmacological tool.

[Dmt1]N/OFQ(1–13)-NH2: a potent nociceptin/orphanin FQ and opioid receptor universal agonist

Intrathecally (i.t.) administered nociceptin/orphanin FQ (N/OFQ) evokes antinociceptive effects in rodents. Recent studies in monkeys demonstrated that i.t. co‐application of N/OFQ and morphine elicits synergistic antinociceptive actions suggesting mixed N/OFQ peptide (NOP) and μ opioid receptor agonists as innovative spinal analgesics. Thus, novel N/OFQ related peptides were synthesized in order to identify and pharmacologically characterize a mixed NOP/ μ opioid receptor agonist.

Synthesis and antimicrobial activity of dermaseptin S1 analogues

Dermaseptins are peptides found in the skin secretions of Phyllomedusinae frogs. These peptides exert lytic action on some microorganisms without substantial haemolysis. In an attempt to understand the antimicrobial activity of these peptides we designed several dermaseptin S1 (ALWKTMLKKLGTMALHAGKAALGAAADTISQGTQ) (DS1) analogues. All peptides were tested on the growth of prokaryotic (Gram-positive and Gram-negative bacteria) and eukaryotic (the yeast Candida albicans and the protozoon Leishmania major) organisms. Our data showed a dose-dependent killing effect by most DS1 derivatives. Maximal antibacterial activity was displayed by a 16-mer peptide that was more active than native DS1.

Further Studies at Neuropeptide S Position 5: Discovery of Novel Neuropeptide S Receptor Antagonists

Neuropeptide S (NPS) regulates various biological functions by activating the NPS receptor (NPSR). Previous studies demonstrated that the substitution of Gly(5) with d-amino acids generates NPSR antagonists. Eleven [d-Xaa(5)]NPS derivatives were synthesized and pharmacologically tested measuring [Ca(2+)](i) in HEK293(mNPSR) cells. The results confirmed that the [d-Xaa(5)] substitution promotes antagonist activity with potency inversely related to the side chain size and allowed identification of the novel potent NPSR peptide antagonist [(t)Bu-d-Gly(5)]NPS.

[Dmt(1) ]N/OFQ(1-13)-NH(2) , a potent nociceptin/orphanin FQ and opioid receptor universal agonist.

Intrathecally (i.t.) administered nociceptin/orphanin FQ (N/OFQ) evokes antinociceptive effects in rodents. Recent studies in monkeys demonstrated that i.t. co‐application of N/OFQ and morphine elicits synergistic antinociceptive actions suggesting mixed N/OFQ peptide (NOP) and μ opioid receptor agonists as innovative spinal analgesics. Thus, novel N/OFQ related peptides were synthesized in order to identify and pharmacologically characterize a mixed NOP/ μ opioid receptor agonist.

In vitro and in vivo pharmacological characterization of nociceptin/orphanin FQ tetrabranched derivatives

An innovative chemical approach, named peptide welding technology (PWT), allows the synthesis of multibranched peptides with extraordinary high yield, purity and reproducibility. With this approach, three different tetrabranched derivatives of nociceptin/orphanin FQ (N/OFQ) have been synthesized and named PWT1‐N/OFQ, PWT2‐N/OFQ and PWT3‐N/OFQ. In the present study we investigated the in vitro and in vivo pharmacological profile of PWT N/OFQ derivatives and compared their actions with those of the naturally occurring peptide.

A novel and facile synthesis of tetra branched derivatives of nociceptin/orphanin FQ.

Branched peptides have been found to be useful in several research fields however their synthesis and purification is complicated. Here we present a novel and facile synthesis of tetra branched derivatives of nociceptin/orphanin FQ (N/OFQ). Three N/OFQ tetra branched derivatives were prepared using novel cores (PWT1, PWT2 and PWT3) containing a maleimido moiety. [Cys(18)]N/OFQ-NH2 was linked to the cores via thiol-Michael reaction characterized by high yield and purity of the desired final product. In the electrically stimulated mouse vas deferens PWT-N/OFQ derivatives mimicked the inhibitory action of the natural sequence showing similar maximal effects and 3 fold higher potencies. The NOP selective antagonist SB-612111 antagonized the effects of N/OFQ and PWT derivatives with similar pKB values (8.02-8.48). In vivo after supraspinal administration PWT2-N/OFQ stimulated food intake in mice mimicking the action of N/OFQ. Compared to the natural peptide PWT2-N/OFQ was 40 fold more potent and elicited larger effects. These findings suggest that the PWT chemical strategy can be successfully applied to biologically active peptides to generate, with unprecedented high purity and yield, tetra branched derivatives displaying an in vitro pharmacological profile similar to that of the natural sequence associated, in vivo, to increased potency and effectiveness.