Structural diversity in<i>de novo</i>cyclic peptide ligands from genetically encoded library technologies

McAllister, Tom E.; Coleman, Oliver D.; Roper, Grace; Kawamura, Akane

doi:10.1002/pep2.24204

Cited by 12 publications

(12 citation statements)

References 94 publications

(178 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[35][36][37] However, the physicochemical properties of the leads generated by library methods can be highly variable, especially if they contain all-L amino acids or polar side chains. [38,39] In the present paper we demonstrate the application of this strategy to 18-membered rings, an important and diverse class of peptide macrocycles. [40]…”

Section: Introductionmentioning

confidence: 87%

Property‐Driven Development of Passively Permeable Macrocyclic Scaffolds Using Heterocycles**

Saunders

Yudin

2022

Angewandte Chemie

View full text Add to dashboard Cite

Passive membrane permeability is a fundamental challenge in the development of bioactive macrocycles. To achieve this objective, chemists have resorted to various strategies, the most common of which is deployment of N‐methylated amino acids and/or D‐amino acids. Here we investigate the effect of heterocyclic grafts on the passive membrane permeability of macrocycles and report the structural consequences of iterative amino acid replacement by azole rings. Through stepwise substitution of amino acid residues for heterocycles, we show that lipophilicity and PAMPA permeability of a macrocycle can be vastly improved. Overall, changes in permeability do not scale linearly as more heterocycles are incorporated, underscoring the subtleties of conformation‐property relationships in this class of molecule. NMR analysis and molecular dynamics simulations provide insights into the structural consequences of the added heterocycles and these frameworks can now be applied as macrocyclic scaffolds for drug discovery.

show abstract

Section: Introductionmentioning

confidence: 87%

Property‐Driven Development of Passively Permeable Macrocyclic Scaffolds Using Heterocycles**

Saunders

Yudin

2022

Angewandte Chemie

View full text Add to dashboard Cite

show abstract

“…While biological approaches allow for the rapid discovery of cyclic peptides from large libraries, 4 − 8 their laboratory synthesis can be challenging. The reduced entropy upon cyclization is a major impediment for the synthesis of cyclic peptides, in addition to other issues such as C-terminal epimerization and oligomerization.…”

Section: Introductionmentioning

confidence: 99%

“…While biological approaches allow for the rapid discovery of cyclic peptides from large libraries, − their laboratory synthesis can be challenging. The reduced entropy upon cyclization is a major impediment for the synthesis of cyclic peptides, in addition to other issues such as C-terminal epimerization and oligomerization. , Moreover, the incorporation of nonpeptidic scaffolds into macrocycles is highly desirable for tuning the cyclic peptide activity and physical properties .…”

Section: Introductionmentioning

confidence: 99%

Gold(I)-Mediated Rapid Cyclization of Propargylated Peptides via Imine Formation

et al. 2022

View full text Add to dashboard Cite

In fundamental research and drug discovery, there is still a need for effective and straightforward chemical approaches for generating cyclic peptides. The divergent synthesis of cyclic peptides remains a challenge, in particular when cyclization is carried out in the presence of unprotected side chains and a nonpeptidic component within the cycle is needed. Herein, we describe a novel and efficient strategy based on Au(I)-mediated cyclization of unprotected peptides through rapid (30–60 min) amine addition on a propargyl group to generate an imine linkage. Mechanistic insights reveal that the reaction proceeds via regioselective Markovnikov’s addition of the amine on the Au(I)-activated propargyl. This strategy was successfully applied to prepare efficiently (56–94%) over 35 diverse cyclic peptides having different sequences and lengths. We have also achieved stereoselective reduction of cyclic imines employing chiral ligands. The practicality of our method was extended for the synthesis of cyclic peptides that bind Lys48-linked di-ubiquitin chains with high affinity, leading to apoptosis of cancer cells.

show abstract

“…[24][25][26] However, the physicochemical properties of the leads generated by library methods can be highly variable, especially if they contain all-L amino acids or polar side chains. 27,28 Given the struggles associated with low cellular permeability of large peptide molecules, a privileged scaffold must engender a reasonably permeable starting point for further structure/activity studies. In the present paper we demonstrate the application of this strategy to 18-membered rings, an important and diverse class of peptide macrocycles.…”

Section: Introductionmentioning

confidence: 99%

Property-driven development of privileged macrocyclic scaffolds using heterocycles

Saunders

Yudin

2022

Preprint

View full text Add to dashboard Cite

Passive membrane permeability is a fundamental challenge in the development of bioactive macrocycles. To achieve this objective, chemists have resorted to various strategies, the most common of which is deployment of N-methylated amino acids and/or D-amino acids. Here we investigate the effect of heterocyclic grafts on the passive membrane permeability of macrocycles and report the structural consequences of iterative amino acid replacement by azole rings. Through stepwise sub-stitution of amino acid residues for heterocycles, we show that lipophilicity and PAMPA permeability of a macrocycle can be vastly improved. Overall, changes in permeability do not scale linearly as more heterocycles are incorporated, underscor-ing the subtleties of conformation-property relationships in this class of molecule. NMR analysis and molecular dynamics simulations provide insights into the structural consequences of the added heterocycles and foreshadow the emergence of privileged macrocyclic scaffolds for drug discovery.

show abstract

Structural diversity inde novocyclic peptide ligands from genetically encoded library technologies

Cited by 12 publications

References 94 publications

Property‐Driven Development of Passively Permeable Macrocyclic Scaffolds Using Heterocycles**

Property‐Driven Development of Passively Permeable Macrocyclic Scaffolds Using Heterocycles**

Gold(I)-Mediated Rapid Cyclization of Propargylated Peptides via Imine Formation

Property-driven development of privileged macrocyclic scaffolds using heterocycles

Contact Info

Product

Resources

About