Design, Synthesis, and Biological Activities of Potent and Selective Somatostatin Analogues Incorporating Novel Peptoid Residues

Tran, Thuy-Anh; Mattern, Ralph–Heiko; Afargan, Michel; Amitay, Oved; Ziv, Ofer; Morgan, Barry A.; Taylor, John E.; Hoyer, Daniel; Goodman, Murray

doi:10.1021/jm970393l

Cited by 32 publications

(30 citation statements)

References 31 publications

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“…PD 168368 is a new class of antagonists described as a peptoid, because this group of antagonists are nonpeptide ligands, which were designed using the chemical structure of the mammalian neuropeptide of interest as a stating point Horwell, 1995). This approach has yielded antagonists for cholecystokinin, somatostatin, tachykinins, and bombesin receptors (Boden et al, 1993;Boyle et al, 1994;Horwell et al, 1994;Horwell, 1995;Eden et al, 1996;Tran et al, 1998;Tokita et al, 2001a). However, little is known about the molecular basis of their affinity and whether they resemble peptide or other nonpeptide ligands in the basis of their selectivity and affinity (Tokita et al, 2001a).…”

Section: Mammalian Bombesin Receptorsmentioning

confidence: 99%

International Union of Pharmacology. LXVIII. Mammalian Bombesin Receptors: Nomenclature, Distribution, Pharmacology, Signaling, and Functions in Normal and Disease States

Jensen

Battey

Spindel³

et al. 2007

Pharmacol Rev

479

720

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Section: Mammalian Bombesin Receptorsmentioning

confidence: 99%

International Union of Pharmacology. LXVIII. Mammalian Bombesin Receptors: Nomenclature, Distribution, Pharmacology, Signaling, and Functions in Normal and Disease States

Jensen

Battey

Spindel³

et al. 2007

Pharmacol Rev

479

720

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“…These peptoids may act as either agonists or antagonists at neuropeptide receptors. To date, several classes of peptoid antagonists for receptors of gastrointestinal (GI) 1 hormones/neurotransmitters have been described including for cholecystokinin (3)(4)(5), somatostatin (6), tachykinins (7)(8)(9), or bombesin (10) receptors. They have been proven useful in helping to examine the role of these receptors in mediating various physiological and pathophysiological processes and they may be useful as therapeutic agents in such conditions as panic attacks (1,2,5).…”

mentioning

confidence: 99%

Tyrosine 220 in the 5th Transmembrane Domain of the Neuromedin B Receptor Is Critical for the High Selectivity of the Peptoid Antagonist PD168368

Tokita¹,

Hocart²,

Katsuno³

et al. 2001

Journal of Biological Chemistry

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Peptoid antagonists are increasingly being described for G protein-coupled receptors; however, little is known about the molecular basis of their binding. Recently, the peptoid PD168368 was found to be a potent selective neuromedin B receptor (NMBR) antagonist. To investigate the molecular basis for its selectivity for the NMBR over the closely related receptor for gastrin-releasing peptide (GRPR), we used a chimeric receptor approach and a site-directed mutagenesis approach. Mutated receptors were transiently expressed in Balb 3T3. The extracellular domains of the NMBR were not important for the selectivity of PD168368. However, substitution of the 5th upper transmembrane domain (uTM5) of the NMBR by the comparable GRPR domains decreased the affinity 16-fold. When the reverse study was performed by substituting the uTM5 of NMBR into the GRPR, a 9-fold increase in affinity occurred. Each of the 4 amino acids that differed between NMBR and GRPR in the uTM5 region were exchanged, but only the substitution of Phe 220 for Tyr in the NMBR caused a decrease in affinity. When the reverse study was performed to attempt to demonstrate a gain of affinity in the GRPR, the substitution of Tyr 219 for Phe caused an increase in affinity. These results suggest that the hydroxyl group of Tyr 220 in uTM5 of NMBR plays a critical role for high selectivity of PD168368 for NMBR over GRPR. Receptor and ligand modeling suggests that the hydroxyl of the Tyr 220 interacts with nitrophenyl group of PD168368 likely primarily by hydrogen bonding. This result shows the selectivity of the peptoid PD168368, similar to that reported for numerous non-peptide analogues with other G protein-coupled receptors, is primarily dependent on interaction with transmembrane amino acids.

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“…There were also attempts to mimic somatostatin, a growth hormone, and azapeptide, a T-cell activator (Tran et al, 1998;Hart & Beeson, 2001) using this technology. Similarly, modifications can be carried out to synthesize peptide resembling a naturally occurring biological substance with suitable modification to obtain desirable properties so that the molecules are able to cross BBB.…”

Section: Peptidomimetics (Mimicking Peptides)mentioning

confidence: 99%

Strategies for drug delivery to the central nervous system by systemic route

et al. 2014

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Context: Delivery of a drug into the central nervous system (CNS) is considered difficult. Most of the drugs discovered over the past decade are biological, which are high in molecular weight and polar in nature. The delivery of such drugs across the blood-brain barrier presents problems.Objective: This review discusses some of the options available to reach the CNS by systemic route. The focus is mainly on the recent developments in systemic delivery of a drug to the CNS. Materials and methods: Databases such as Scopus, Google scholar, Science Direct, SciFinder and online journals were referred for preparing this article including 89 references. Results: There are at least nine strategies that could be adopted to achieve the required drug concentration in the CNS. Conclusion: The recent developments in drug delivery are very promising to deliver biologicals into the CNS.

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Design, Synthesis, and Biological Activities of Potent and Selective Somatostatin Analogues Incorporating Novel Peptoid Residues

Cited by 32 publications

References 31 publications

International Union of Pharmacology. LXVIII. Mammalian Bombesin Receptors: Nomenclature, Distribution, Pharmacology, Signaling, and Functions in Normal and Disease States

International Union of Pharmacology. LXVIII. Mammalian Bombesin Receptors: Nomenclature, Distribution, Pharmacology, Signaling, and Functions in Normal and Disease States

Tyrosine 220 in the 5th Transmembrane Domain of the Neuromedin B Receptor Is Critical for the High Selectivity of the Peptoid Antagonist PD168368

Strategies for drug delivery to the central nervous system by systemic route

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