Methods for the Creation of Cyclic Peptide Libraries for Use in Lead Discovery

Foster, Andrew D.; Ingram, James D.; Leitch, Eilidh K.; Lennard, Katherine R.; Osher, Eliot; Tavassoli, Ali

doi:10.1177/1087057114566803

Cited by 37 publications

(30 citation statements)

References 103 publications

(149 reference statements)

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“…Ribosome display links the amino acid library directly to the ribosome and the encoding mRNA. Alternatively, in mRNA display, translated mRNA is covalently linked to the protein through an adaptor molecule [ 65 ]. These techniques have each been used to display and select peptides and antibody fragments [ 64 , 66 , 67 ].…”

Section: Methodology Overviewmentioning

confidence: 99%

In VitroSelection of Cancer Cell-Specific Molecular Recognition Elements from Amino Acid Libraries

Williams

Sooter

2015

Journal of Immunology Research

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Differential cell systematic evolution of ligands by exponential enrichment (SELEX) is an in vitro selection method for obtaining molecular recognition elements (MREs) that specifically bind to individual cell types with high affinity. MREs are selected from initial large libraries of different nucleic or amino acids. This review outlines the construction of peptide and antibody fragment libraries as well as their different host types. Common methods of selection are also reviewed. Additionally, examples of cancer cell MREs are discussed, as well as their potential applications.

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Section: Methodology Overviewmentioning

confidence: 99%

In VitroSelection of Cancer Cell-Specific Molecular Recognition Elements from Amino Acid Libraries

Williams

Sooter

2015

Journal of Immunology Research

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“…There are many methods to create libraries of cyclic peptides (reviewed in [50]), some of which have been implemented in the search for anti-amyloidogenic agents. As mentioned before, heterocyclic peptides have been studied in many antiamyloidogenic therapeutic approaches.…”

Section: Anti-amyloidogenic Heterocyclic Peptidesmentioning

confidence: 99%

Anti-amyloidogenic Heterocyclic Peptides

Chemerovski-Glikman

Richman

Rahimipour

2016

Topics in Heterocyclic Chemistry

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The amyloid fibril is a highly ordered proteinous aggregate, originally discovered in the context of the self-assembly of soluble proteins into insoluble extracellular plaques. The molecular structure of amyloidosis, an energetically stable conformation with a thermodynamic local minimum, is of particular interest because of its possible pathogenicity. Amyloidogenic diseases (amyloidoses) are often fatal, widely heterogenic, and caused by sporadic, genetic, or infectious pathogens. Consequently, major effort has been directed in the past few decades to identify and develop agents that decrease the concentration of the pathogenic aggregates either by interfering with the self-assembly of the proteins or by modulating their physiological concentration. Heterocyclic peptides of natural and synthetic origin have gained special attention because of their demonstrated ability to interact with various amyloids. In addition to interfering with the amyloid aggregation process, many of the discovered peptides also inhibit the formation of fibrils, disassemble preformed fibrils, and prevent the pathogenic seeding effect. Others are instrumental candidates for passive vaccination against amyloid deposits. The promising preliminary results described here, together with the broad chemical diversity of heterocyclic peptides and their amenability to largescale production, make these compounds promising for anti-amyloidogenic research and for pharmacological therapy of amyloidoses.

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“…Since these methodologies have been the subject of several recent, exhaustive reviews [6–10], we will provide here only a brief overview of them. The proper method of choice depends on the nature of the PPI in question and the expertise available within a research laboratory.…”

Section: Generating Cyclic Peptides As Ppi Inhibitorsmentioning

confidence: 99%

Targeting intracellular protein–protein interactions with cell-permeable cyclic peptides

Qian

Dougherty

Pei

2017

Current Opinion in Chemical Biology

113

109

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Intracellular protein-protein interactions (PPIs) are challenging targets for conventional drug modalities, because small molecules generally do not bind to their large, flat binding sites with high affinity, whereas monoclonal antibodies cannot cross the cell membrane to reach the targets. Cyclic peptides in the 700–2000 molecular-weight range have the sufficient size and a balanced conformational flexibility/rigidity for binding to flat PPI interfaces with antibody-like affinity and specificity. Several powerful cyclic peptide library technologies were developed over the past decade to rapidly discover potent, specific cyclic peptide ligands against proteins of interest including those involved in PPIs. Methods are also being developed to enhance the membrane permeability of cyclic peptides through both passive diffusion and active transport mechanisms. Integration of the permeability-enhancing elements into cyclic peptide design has led to an increasing number of cell-permeable and biologically active cyclic peptides against intracellular PPIs. In this account, we review the recent developments in the design and synthesis of cell-permeable cyclic peptides.

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Methods for the Creation of Cyclic Peptide Libraries for Use in Lead Discovery

Cited by 37 publications

References 103 publications

In VitroSelection of Cancer Cell-Specific Molecular Recognition Elements from Amino Acid Libraries

In VitroSelection of Cancer Cell-Specific Molecular Recognition Elements from Amino Acid Libraries

Anti-amyloidogenic Heterocyclic Peptides

Targeting intracellular protein–protein interactions with cell-permeable cyclic peptides

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