Design of RNA-targeting macrocyclic peptides

Walker, Matthew; Varani, Gabriele

doi:10.1016/bs.mie.2019.04.029

Cited by 11 publications

(10 citation statements)

References 93 publications

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“…Although the field of de novo designed proteins capable of binding to nucleic acids is relatively under researched, there have been advances that use other design methods which may offer engineering insights. Walker and Varani discuss their approach in designing peptides capable of binding to RNA, which focused mainly on structure based peptidomimetics [ 61 ]. These are designed peptides meant to mimic the sequence and structure of proteins known to interact with RNA.…”

Section: Design Of Dna/rna Binding Proteinsmentioning

confidence: 99%

Recent Progress Using De Novo Design to Study Protein Structure, Design and Binding Interactions

Ferrando

Solomon

2021

Life

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De novo protein design is a powerful methodology used to study natural functions in an artificial-protein context. Since its inception, it has been used to reproduce a plethora of reactions and uncover biophysical principles that are often difficult to extract from direct studies of natural proteins. Natural proteins are capable of assuming a variety of different structures and subsequently binding ligands at impressively high levels of both specificity and affinity. Here, we will review recent examples of de novo design studies on binding reactions for small molecules, nucleic acids, and the formation of protein-protein interactions. We will then discuss some new structural advances in the field. Finally, we will discuss some advancements in computational modeling and design approaches and provide an overview of some modern algorithmic tools being used to design these proteins.

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Section: Design Of Dna/rna Binding Proteinsmentioning

confidence: 99%

Recent Progress Using De Novo Design to Study Protein Structure, Design and Binding Interactions

Ferrando

Solomon

2021

Life

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“…Many RNA binding proteins recognize RNA molecules through arginine-rich motifs (ARMs), as they are relatively shorter in length, have little sequence similarity (aside from containing many arginine residues), and adopt diverse conformations (including an α-helix and a β-hairpin) upon association with the viral RNA. − The experimental work using X-ray crystallography and nuclear magnetic resonance (NMR) methods on the peptide–RNA complexes has demonstrated that the RNA backbone interacts with peptides more commonly than the nucleotide bases, suggesting that the majority of peptide–RNA interactions are nonspecific. , Overall, these studies showed that the peptide–RNA interactions occur through dynamic rearrangements in both molecules, which often entail backbone shifts and the flipping of nucleobases and amino acid residues. , Moreover, recent studies have demonstrated that the β-hairpin peptides could be synthesized with ultrahigh affinity toward viral RNA molecules. − However, a de novo design of α-helical peptides that potently and selectively recognize viral RNA molecules is limited due to a poor understanding of the RNA recognition mechanism.…”

Section: Introductionmentioning

confidence: 99%

Role of Mutations in Differential Recognition of Viral RNA Molecules by Peptides

Kumar

Vashisth

2022

J. Chem. Inf. Model.

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The conserved noncoding RNA elements in viral genomes interact with proteins to regulate various events during viral replication. We report studies on the recognition mechanisms of two helical peptides, namely, a native (Rev) peptide and a lab-evolved (RSG1.2) peptide, by a highly conserved viral RNA element from the human immunodeficiency virus 1 genome. Specifically, we investigated the physical interactions between the viral RNA molecule and helical peptides by computing free energy changes on mutating key amino acid residues involved in recognition of an internal loop in the viral RNA molecule.

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“…The peptide hydrogen bond (HB) is a crucial non-covalent interaction that is implicated in the stabilization of various secondary structures like β-turn 1, 2 , 3 10 -helix [3][4][5] , α-helix 6,7 , π-helix 8 , random loops 9,10 . These secondary structures play important roles in several biological recognition processes through protein-protein 11,12 , protein-DNA 13,14 , protein-RNA interactions 15,16 and as hormones 9, 10 , antibiotics 1, 2 , ion-channels 3,4,[17][18][19] and in signal transduction 20 , protein folding 21,22 . Recognitions tend to be prevalently along with peptide sequences between the hydrogen bond constraint 23,24 .…”

Section: Introductionmentioning

confidence: 99%

“…Seal the separatory funnel again with polyethylene cap, shake the reaction mixture and settle down for 2 min until two layers are separated out. 16. separate the aqueous layer and pass the organic layer through the crystalline sodium sulphate to remove the residual amount of water and collect in 100 ml one neck RBF.…”

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confidence: 99%

Large Scale Synthesis of Native Turn and Helix Mimics Stabilized by a Generic Hydrogen Bond Surrogate

Prabhakaran

Pal

Kumar

et al. 2021

Preprint

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Short Turn and Helix mimics frequently represent molecular recognition surfaces perturbing bio-relevant protein-biomolecular interfaces. Generic methods that can stabilize short peptides into turns or helices by retaining all recognition elements, have tremendous applications in drug discovery. Here, a versatile modular synthetic protocol is presented for stabilizing turns and helices of different sizes by replacing their ring-closing hydrogen bonds with a generic three-carbon covalent surrogate. Two Fukuyama-Mitsunobu reactions insert the surrogate between desired residues in high yields and purity. Coupling with turn size-dependent oligopeptides containing both sterically restricted and non-coded residues, followed by macrolactamization yield a variety of stabilized turns. Short peptide extensions at the C-terminus of these turns yield stabilized 310-helices and α-helices. This solution-phase synthetic approach provides combinatorial access to libraries of stabilized turns and helices with all their native residues retained, in >100 mmole scales, in about one week per stabilized mimic, to technicians with postgraduate level training.

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Design of RNA-targeting macrocyclic peptides

Cited by 11 publications

References 93 publications

Recent Progress Using De Novo Design to Study Protein Structure, Design and Binding Interactions

Recent Progress Using De Novo Design to Study Protein Structure, Design and Binding Interactions

Role of Mutations in Differential Recognition of Viral RNA Molecules by Peptides

Large Scale Synthesis of Native Turn and Helix Mimics Stabilized by a Generic Hydrogen Bond Surrogate

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