Oligo(<i>N-</i>aryl glycines): A New Twist on Structured Peptoids

Shah, Neel H.; Butterfoss, Glenn L.; Nguyen, Khanh K.; Yoo, Barney; Bonneau, Richard; Rabenstein, Dallas L.; Kirshenbaum, Kent

doi:10.1021/ja804580n

Cited by 192 publications

(270 citation statements)

References 76 publications

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“…Finally, the thioamide analog 15, like β-peptoid 12e, exhibited higher K cis/trans values than its oxoamide analog (13) in polar solvents, and a significant decrease in the cisamide fraction in CDCl 3 (Chart 1). This again indicates that there is an interaction between the sulfur and the aromatic residue, which results in favoring of the cis-amide conformation.…”

Section: −10mentioning

confidence: 99%

“…9,29 Finally, peptoid studies have also shown that direct attachment of a phenyl group to the nitrogen atom (i.e., prepared from aniline subunits) leads to a very strong preference for trans-amides. 13 A single β-peptoid model system of this type (5h) was evaluated and exhibited the expected selectivity, by virtually giving rise to single sets of signals in all tested solvents when analyzed by 1 H NMR. As mentioned, we also evaluated the entire series of side chains a−h in model systems having C-terminal amides (6a−6h) instead of esters, to mimic the environment of a β-peptoid residue within an oligomer more appropriately.…”

Section: −10mentioning

confidence: 99%

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Cis–Trans Amide Bond Rotamers in β-Peptoids and Peptoids: Evaluation of Stereoelectronic Effects in Backbone and Side Chains

et al. 2013

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Non-natural peptide analogs have significant potential for the development of new materials and pharmacologically active ligands. One such architecture, the β-peptoids (N-alkyl-β-alanines), has found use in a variety of biologically active compounds but has been sparsely studied with respect to folding propensity. Thus, we here report an investigation of the effect of structural variations on the cis−trans amide bond rotamer equilibria in a selection of monomer model systems. In addition to various side chain effects, which correlated well with previous studies of α-peptoids, we present the synthesis and investigation of cis−trans isomerism in the first examples of peptoids and β-peptoids containing thioamide bonds as well as trifluoroacetylated peptoids and β-peptoids. These systems revealed an increase in the preference for cis-amides as compared to their parent compounds and thus provide novel strategies for affecting the folding of peptoid constructs. By using NMR spectroscopy, X-ray crystallographic analysis, and density functional theory calculations, we present evidence for the presence of thioamide−aromatic interactions through C sp 2 −H•••S amide hydrogen bonding, which stabilize certain peptoid conformations.

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Section: −10mentioning

confidence: 99%

Section: −10mentioning

confidence: 99%

Cis–Trans Amide Bond Rotamers in β-Peptoids and Peptoids: Evaluation of Stereoelectronic Effects in Backbone and Side Chains

et al. 2013

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“…17 It has become clear that proteinpeptide interactions are very abundant in the cell and estimates suggest they represent 15-40% of all interactions, 18 making peptide discovery and development of wide applicability and interest. Cyclic peptides [19][20][21][22] and other modified peptides 23,24 can be highly potent as well as selective, providing a compromise between structural preorganization and sufficient flexibility to mold to a target surface and maximize binding interactions. There is much evidence that despite having molecular masses well above Lipinski's rule constraints, cyclic peptides and other macrocycles can possess drug-like physicochemical and pharmacokinetic properties such as good solubility, lipophilicity, metabolic stability and bioavailability.…”

Section: Introductionmentioning

confidence: 99%

Peptidic modulators of protein‐protein interactions: Progress and challenges in computational design

Rubinstein

Niv

2009

Biopolymers

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With the decline in productivity of drug‐development efforts, novel approaches to rational drug design are being introduced and developed. Naturally occurring and synthetic peptides are emerging as novel promising compounds that can specifically and efficiently modulate signaling pathways in vitro and in vivo. We describe sequence‐based approaches that use peptides to mimic proteins in order to inhibit the interaction of the mimicked protein with its partners. We then discuss a structure‐based approach, in which protein‐peptide complex structures are used to rationally design and optimize peptidic inhibitors. We survey flexible peptide docking techniques and discuss current challenges and future directions in the rational design of peptidic inhibitors. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 505–513, 2009.This article was originally published online as an accepted preprint. The “Published Online”date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com

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“…For the N-aryl peptoid, local structure is controlled by incorporation of side chain groups that restrict the possible backbone conformational states through both steric and electronic effects. N-aryl side chains restrict the amide backbone nearly exclusively to the trans state (19) and the bulky iodo-and tert-butyl-substituents lead to additional biasing of the φ torsion (30). Unbranched N-alkyl side chains provide fewer local restrictions to the peptoid backbone (31), but can contribute to long-range interactions that can direct chain folding (12).…”

Section: Conformational Landscapes Of Foldable and Nonfoldable Peptoidmentioning

confidence: 99%

“…Such helices have been used to form tertiary assemblies (11, 16), and have been incorporated into enzymes with minimal loss of function (17). Alternatively, peptoid N-aryl side chains have been used to induce trans-amide helices that can mimic polyproline II structure (18,19). It remains to be determined how these local rules can be used to control the global three-dimensional structure of peptoid macromolecules (20).…”

mentioning

confidence: 99%

De novo structure prediction and experimental characterization of folded peptoid oligomers

Butterfoss

Yoo

Jaworski

et al. 2012

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

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108

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Peptoid molecules are biomimetic oligomers that can fold into unique three-dimensional structures. As part of an effort to advance computational design of folded oligomers, we present blind-structure predictions for three peptoid sequences using a combination of Replica Exchange Molecular Dynamics (REMD) simulation and Quantum Mechanical refinement. We correctly predicted the structure of a N-aryl peptoid trimer to within 0.2 Å rmsd-backbone and a cyclic peptoid nonamer to an accuracy of 1.0 Å rmsd-backbone. X-ray crystallographic structures are presented for a linear N-alkyl peptoid trimer and for the cyclic peptoid nonamer. The peptoid macrocycle structure features a combination of cis and trans backbone amides, significant nonplanarity of the amide bonds, and a unique "basket" arrangement of (S)-N(1-phenylethyl) side chains encompassing a bound ethanol molecule. REMD simulations of the peptoid trimers reveal that well folded peptoids can exhibit funnel-like conformational free energy landscapes similar to those for ordered polypeptides. These results indicate that physical modeling can successfully perform de novo structure prediction for small peptoid molecules.foldamer | molecular simulation F oldamers are synthetic polymers that-like proteins-have the ability to self-assemble into unique folded structures (1). Examples of foldamer systems include β-peptides, γ-peptides, azapeptides, oligoureas, arylamides, oligohydrazides, polyphenylacetylenes, and peptoids, among others (2, 3). Of these, peptoids offer an attractive platform for designing functionalized, conformationally ordered molecular architectures ( Fig. 1): they can be readily synthesized to incorporate chemically diverse side chains (4, 5), are resistant to proteolysis (6), and can retain structure and function in nonaqueous solvents. Peptoids have found capacity for diverse applications such as antimicrobials (7), drug delivery platforms (8), therapeutics (9), enantioselective catalysts (10), and nanostructured materials (11,12).Unlike peptides, peptoids lack the ability to form backbone hydrogen bonds and can readily populate both cis and trans backbone amide states. Thus, new strategies may be required to enable the rational design of ordered peptoid structures. For instance, even though the peptoid backbone is achiral, bulky chiral side chain groups such as 1-phenylethyl or 1-naphthylethyl can be used to induce stereocontrolled cis-amide helical structures resembling polyproline I (13-15). Such helices have been used to form tertiary assemblies (11, 16), and have been incorporated into enzymes with minimal loss of function (17). Alternatively, peptoid N-aryl side chains have been used to induce trans-amide helices that can mimic polyproline II structure (18,19). It remains to be determined how these local rules can be used to control the global three-dimensional structure of peptoid macromolecules (20).In order to design peptoids for applications, we need a way to predict their native structures from their sequences. Successes in designing prot...

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Oligo(N-aryl glycines): A New Twist on Structured Peptoids

Cited by 192 publications

References 76 publications

Cis–Trans Amide Bond Rotamers in β-Peptoids and Peptoids: Evaluation of Stereoelectronic Effects in Backbone and Side Chains

Cis–Trans Amide Bond Rotamers in β-Peptoids and Peptoids: Evaluation of Stereoelectronic Effects in Backbone and Side Chains

Peptidic modulators of protein‐protein interactions: Progress and challenges in computational design

De novo structure prediction and experimental characterization of folded peptoid oligomers

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