<i>N</i>,<i>N</i>‘-Linked Oligoureas as Foldamers: Chain Length Requirements for Helix Formation in Protic Solvent Investigated by Circular Dichroism, NMR Spectroscopy, and Molecular Dynamics

Violette, Aude; Averlant-Petit, Marie Christine; Semetey, Vincent; Hemmerlin, Christine; Casimir, Richard; Graff, Roland; Marraud, Michel; Briand, Jean‐Paul; Rognan, Didier; Guichard, Gilles

doi:10.1021/ja044392b

Cited by 158 publications

(144 citation statements)

References 48 publications

(46 reference statements)

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“…[27] N,N'-Linked oligoureas with proteinogenic side chains (13, Figure 3) are mimics of peptides whose preferred helical conformation results from intramolecular hydrogen bonds. [28,29] Those foldamers are unique scaffolds for potential use in a range of biological and biomedical applications. [30] Glycoluril and formaldehyde condense under acidic conditions to deliver the cucurbit[n]urils 14 (Figure 4), which consist of n glycoluril units that are joined to the next one by two methylene bridges to form a closed band in which the urea oxygen atoms are tilted inwards, thus forming a partly enclosed cavity.…”

Section: Conformation Of Substituted Ureasmentioning

confidence: 99%

The Urea Renaissance

2011

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Over the last decade the use of urea derivatives as useful reagents, catalysts, and structural features in organic chemistry has increased rapidly. They now find utility as hydrogen-bond donors in organocatalysts and anion transporters, as important scaffolds in supramolecular chemistry, as lithiation directors, amination substrates, and promoters of metalation, and as substrates for novel rearrangement reactions. Highlighted herein is the remarkably rapid and recent development of the chemistry of ureas, which for many years had been considered unreactive, intractable, and of little value.

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Section: Conformation Of Substituted Ureasmentioning

confidence: 99%

The Urea Renaissance

2011

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“…[27] N,N'-Gekuppelte Oligoharnstoffe mit proteinogenen Seitenketten (13; Abbildung 3) wirken als Mimetika von Peptiden, deren bevorzugte schraubenfçrmige Konformation aus intramolekularen Wasserstoffbrücken resultiert. [28,29] Solche Foldamere sind einzigartige Gerüste für eine Reihe von biologischen und biomedizinischen Anwendungen. [30] Glycoluril und Formaldehyd kondensieren unter sauren Bedingungen zu den Cucurbit[n]urilen (14; Abbildung 4), die (14) und Cucurbit [7]uril (14a).…”

Section: Konformation Substituierter Harnstoffeunclassified

Die Harnstoff‐Renaissance

Volz

Clayden

2011

Angewandte Chemie

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Im letzten Jahrzehnt hat die Verwendung von Harnstoffderivaten als wertvolle Reagentien, Katalysatoren und Struktureinheiten in der organischen Chemie rasch zugenommen. Sie finden nun Verwendung als Wasserstoffbrückendonoren in Organokatalysatoren und Anionentransportern, als wichtige Struktureinheit in der supramolekularen Chemie, für die Steuerung von Lithiierungen, als Aminierungssubstrate, für die Vermittlung von Metallierungen und als Substrate für neuartige Umlagerungen. In diesem Aufsatz wird die bemerkenswert rasche aktuelle Entwicklung der Chemie des Harnstoffs hervorgehoben, der für viele Jahre als unreaktiv, schwer zu handhaben und vergleichsweise wertlos betrachtet wurde.

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“…Poly-N-substituted glycines (peptoids) comprise another class of peptidomimetics that differ from peptides only in that peptoid side chains are attached to the backbone amide nitrogen rather than to the ␣-carbon (27), making them protease-resistant (28). More than any of the other peptidomimetic systems under study (29), including ␤-peptides (26,30), ␤-peptoids (31), oligoureas (32), and oligo(phenylene ethynylene)s (33), peptoids (34)(35)(36) are particularly well suited for AMP mimicry because they are easily synthesized on solid phase (by using conventional peptide synthesis equipment) with access to diverse sequences at relatively low cost (27). Any chemical functionality available as a primary amine can be incorporated via a submonomer synthetic method (27); thus, peptoids are highly and finely tunable.…”

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Peptoids that mimic the structure, function, and mechanism of helical antimicrobial peptides

Chongsiriwatana¹,

Patch²,

Czyzewski³

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

567

578

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Antimicrobial peptides (AMPs) and their mimics are emerging as promising antibiotic agents. We present a library of ''ampetoids'' (antimicrobial peptoid oligomers) with helical structures and biomimetic sequences, several members of which have low-micromolar antimicrobial activities, similar to cationic AMPs like pexiganan. Broad-spectrum activity against six clinically relevant BSL2 pathogens is also shown. This comprehensive structure-activity relationship study, including circular dichroism spectroscopy, minimum inhibitory concentration assays, hemolysis and mammalian cell toxicity studies, and specular x-ray reflectivity measurements shows that the in vitro activities of ampetoids are strikingly similar to those of AMPs themselves, suggesting a strong mechanistic analogy. The ampetoids' antibacterial activity, coupled with their low cytotoxicity against mammalian cells, make them a promising class of antimicrobials for biomedical applications. Peptoids are biostable, with a protease-resistant N-substituted glycine backbone, and their sequences are highly tunable, because an extensive diversity of side chains can be incorporated via facile solid-phase synthesis. Our findings add to the growing evidence that nonnatural foldamers will emerge as an important class of therapeutics.antibiotics ͉ peptidomimetics ͉ structure-activity studies N atural antimicrobial peptides (AMPs) defend a wide array of organisms against bacterial pathogens and show potential as supplements for or replacements of conventional antibiotics, because few bacteria have evolved resistance to them (1-3). Many AMPs kill bacteria by permeabilization of the cytoplasmic membrane, causing depolarization, leakage, and death (4), whereas others target additional anionic bacterial constituents (e.g., DNA, RNA, or cell wall components) (2, 5). Amphipathic secondary structures in which residues are segregated into hydrophobic and cationic regions ( Fig. 1 A and B) are the hallmark of most AMPs (6). Regardless of their final target of killing, AMPs must interact with the bacterial cytoplasmic membrane, and their amphipathicity is integral to such interactions (1, 2, 7). Additionally, their cationic nature imparts AMPs with some measure of selectivity, because mammalian cell membranes are largely zwitterionic. The precise nature of AMP-membrane interactions remains controversial and actively debated; a variety of mechanisms have been proposed, including the carpet (4), barrel-stave pore (4), toroidal pore (8), and aggregate (9) models. Nevertheless, a considerable number of structure-activity investigations have elucidated how the physicochemical properties of these molecules relate to their biological activities (4,7,(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20)(21)(22).Although AMPs have been actively studied for decades (23-25), they have yet to see widespread clinical use (1). This is due in part to the vulnerability of many peptide therapeutics to rapid in vivo degradation, which dramatically reduces their bioavailability. Nonnatural mimics of AMPs...

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N,N‘-Linked Oligoureas as Foldamers: Chain Length Requirements for Helix Formation in Protic Solvent Investigated by Circular Dichroism, NMR Spectroscopy, and Molecular Dynamics

Cited by 158 publications

References 48 publications

The Urea Renaissance

The Urea Renaissance

Die Harnstoff‐Renaissance

Peptoids that mimic the structure, function, and mechanism of helical antimicrobial peptides

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