Structure-Permeability Relationship of Semipeptidic Macrocycles-Understanding and Optimizing Passive Permeability and Efflux Ratio

Overview

Journal J Med Chem

Publisher American Chemical Society

Specialty Chemistry

Date 2020 May 27

PMID 32453569

Citations 13

Authors

Antoine Le Roux

Emilie Blaise

Pierre-Luc Boudreault

Christian Comeau

Annie Doucet

Marilena Giarrusso

Marie-Pierre Collin

Thomas Neubauer

Florian Kolling

Andreas H Goller

Lea Seep

Dieudonne T Tshitenge

Matthias Wittwer

Maximilian Kullmann

Alexander Hillisch

Joachim Mittendorf

Eric Marsault

Affiliations

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Abstract

We herein report the first thorough analysis of the structure-permeability relationship of semipeptidic macrocycles. In total, 47 macrocycles were synthesized using a hybrid solid-phase/solution strategy, and then their passive and cellular permeability was assessed using the parallel artificial membrane permeability assay (PAMPA) and Caco-2 assay, respectively. The results indicate that semipeptidic macrocycles generally possess high passive permeability based on the PAMPA, yet their cellular permeability is governed by efflux, as reported in the Caco-2 assay. Structural variations led to tractable structure-permeability and structure-efflux relationships, wherein the linker length, stereoinversion, N-methylation, and peptoids site-specifically impact the permeability and efflux. Extensive nuclear magnetic resonance, molecular dynamics, and ensemble-based three-dimensional polar surface area (3D-PSA) studies showed that ensemble-based 3D-PSA is a good predictor of passive permeability.

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