Morphology Transformation of Foldamer Assemblies Triggered by Single Oxygen Atom on Critical Residue Switch

Byung-Chang Oh; Eunyoung Yoon; Jintaek Gong; Jaewook Kim; Russell W. Driver; Yongjun Kim; Woo Youn Kim; Hee-Seung Lee

doi:10.1002/smll.202102525

Morphology Transformation of Foldamer Assemblies Triggered by Single Oxygen Atom on Critical Residue Switch

Byung-Chang Oh
, Eunyoung Yoon
, Jintaek Gong
, Jaewook Kim
, Russell W. Driver
, Yongjun Kim
, Woo Youn Kim
, Hee-Seung Lee

Research output: Contribution to journal › Article › peer-review

Abstract

The synthesis of morphologically well-defined peptidic materials via self-assembly is challenging but demanding for biocompatible functional materials. Moreover, switching morphology from a given shape to other predictable forms by molecular modification of the identical building block is an even more complicated subject because the self-assembly of flexible peptides is prone to diverge upon subtle structural change. To accomplish controllable morphology transformation, systematic self-assembly studies are performed using congener short β-peptide foldamers to find a minimal structural change that alters the self-assembled morphology. Introduction of oxygen-containing β-amino acid (ATFC) for subtle electronic perturbation on hydrophobic foldamers induces a previously inaccessible solid-state conformational split to generate the most susceptible modification site for morphology transformation of the foldamer assemblies. The site-dependent morphological switching power of ATFC is further demonstrated by dual substitution experiments and proven by crystallographic analyses. Stepwise morphology transformation is shown by modifying an identical foldamer scaffold. This study will guide in designing peptidic molecules from scratch to create complex and biofunctional assemblies with nonspherical shapes.

Original language	American English
Article number	2102525
Journal	Small
Volume	17
Issue number	36
DOIs	https://doi.org/10.1002/smll.202102525
State	Published - Jul 26 2021

Bibliographical note

Publisher Copyright:
© 2021 The Authors. Small published by Wiley-VCH GmbH

Funding

This work was supported by the National Research Foundation of Korea (NRF) grants funded by the Korea government (MSIT and Ministry of Education) (No. 2018R1A5A1025208 and No. 2019R1A61A10073887). R.W.D. acknowledges a President's Faculty Research and Development Grant (No. 334835). The synchrotron powder and single‐crystal X‐ray diffraction data for structure determination were collected from the 9B and 2D beamline at the Pohang Accelerator Laboratory (Pohang, Republic of Korea), respectively.

Funders	Funder number
Ministry of Education	2018R1A5A1025208, 2019R1A61A10073887, 334835
Ministry of Education
Ministry of Science, ICT and Future Planning
National Research Foundation of Korea

ASJC Scopus Subject Areas

General Chemistry
Engineering (miscellaneous)
Biotechnology
General Materials Science
Biomaterials

Keywords

crystal engineering
foldamers
morphology transformation
self-assembly
supramolecules

Disciplines

Materials Chemistry
Organic Chemistry
Computational Chemistry

Access to Document

10.1002/smll.202102525License: CC BY-NC-ND

Cite this

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title = "Morphology Transformation of Foldamer Assemblies Triggered by Single Oxygen Atom on Critical Residue Switch",

abstract = " The synthesis of morphologically well-defined peptidic materials via self-assembly is challenging but demanding for biocompatible functional materials. Moreover, switching morphology from a given shape to other predictable forms by molecular modification of the identical building block is an even more complicated subject because the self-assembly of flexible peptides is prone to diverge upon subtle structural change. To accomplish controllable morphology transformation, systematic self-assembly studies are performed using congener short β-peptide foldamers to find a minimal structural change that alters the self-assembled morphology. Introduction of oxygen-containing β-amino acid (ATFC) for subtle electronic perturbation on hydrophobic foldamers induces a previously inaccessible solid-state conformational split to generate the most susceptible modification site for morphology transformation of the foldamer assemblies. The site-dependent morphological switching power of ATFC is further demonstrated by dual substitution experiments and proven by crystallographic analyses. Stepwise morphology transformation is shown by modifying an identical foldamer scaffold. This study will guide in designing peptidic molecules from scratch to create complex and biofunctional assemblies with nonspherical shapes.",

keywords = "crystal engineering, foldamers, morphology transformation, self-assembly, supramolecules",

author = "Byung-Chang Oh and Eunyoung Yoon and Jintaek Gong and Jaewook Kim and Driver, \{Russell W.\} and Yongjun Kim and Kim, \{Woo Youn\} and Hee-Seung Lee",

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year = "2021",

month = jul,

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doi = "10.1002/smll.202102525",

language = "American English",

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AU - Oh, Byung-Chang

AU - Yoon, Eunyoung

AU - Gong, Jintaek

AU - Kim, Jaewook

AU - Driver, Russell W.

AU - Kim, Yongjun

AU - Kim, Woo Youn

AU - Lee, Hee-Seung

PY - 2021/7/26

Y1 - 2021/7/26

N2 - The synthesis of morphologically well-defined peptidic materials via self-assembly is challenging but demanding for biocompatible functional materials. Moreover, switching morphology from a given shape to other predictable forms by molecular modification of the identical building block is an even more complicated subject because the self-assembly of flexible peptides is prone to diverge upon subtle structural change. To accomplish controllable morphology transformation, systematic self-assembly studies are performed using congener short β-peptide foldamers to find a minimal structural change that alters the self-assembled morphology. Introduction of oxygen-containing β-amino acid (ATFC) for subtle electronic perturbation on hydrophobic foldamers induces a previously inaccessible solid-state conformational split to generate the most susceptible modification site for morphology transformation of the foldamer assemblies. The site-dependent morphological switching power of ATFC is further demonstrated by dual substitution experiments and proven by crystallographic analyses. Stepwise morphology transformation is shown by modifying an identical foldamer scaffold. This study will guide in designing peptidic molecules from scratch to create complex and biofunctional assemblies with nonspherical shapes.

AB - The synthesis of morphologically well-defined peptidic materials via self-assembly is challenging but demanding for biocompatible functional materials. Moreover, switching morphology from a given shape to other predictable forms by molecular modification of the identical building block is an even more complicated subject because the self-assembly of flexible peptides is prone to diverge upon subtle structural change. To accomplish controllable morphology transformation, systematic self-assembly studies are performed using congener short β-peptide foldamers to find a minimal structural change that alters the self-assembled morphology. Introduction of oxygen-containing β-amino acid (ATFC) for subtle electronic perturbation on hydrophobic foldamers induces a previously inaccessible solid-state conformational split to generate the most susceptible modification site for morphology transformation of the foldamer assemblies. The site-dependent morphological switching power of ATFC is further demonstrated by dual substitution experiments and proven by crystallographic analyses. Stepwise morphology transformation is shown by modifying an identical foldamer scaffold. This study will guide in designing peptidic molecules from scratch to create complex and biofunctional assemblies with nonspherical shapes.

KW - crystal engineering

KW - foldamers

KW - morphology transformation

KW - self-assembly

KW - supramolecules

UR - https://onlinelibrary.wiley.com/doi/10.1002/smll.202102525

UR - https://nsuworks.nova.edu/cnso_chemphys_facarticles/296/

U2 - 10.1002/smll.202102525

DO - 10.1002/smll.202102525

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VL - 17

JO - Small

JF - Small

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M1 - 2102525

ER -

Morphology Transformation of Foldamer Assemblies Triggered by Single Oxygen Atom on Critical Residue Switch

Abstract

Bibliographical note

Funding

ASJC Scopus Subject Areas

Keywords

Disciplines

Access to Document

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