Engineering β-Sheet Peptide Coassemblies for Biomaterial Applications

Kong M. Wong; Alicia S. Robang; Annabelle H. Lint; Yiming Wang; Xin Dong; Xingqing Xiao; Dillon T. Seroski; Renjie Liu; Qing Shao; Gregory A. Hudalla; Carol K. Hall; Anant K. Paravastu

doi:10.1021/acs.jpcb.1c04873

Engineering β-Sheet Peptide Coassemblies for Biomaterial Applications

Kong M. Wong
, Alicia S. Robang
, Annabelle H. Lint
, Yiming Wang
, Xin Dong
, Xingqing Xiao
, Dillon T. Seroski
, Renjie Liu
, Qing Shao
, Gregory A. Hudalla
, Carol K. Hall
, Anant K. Paravastu

Producción científica: Review article › revisión exhaustiva

17 Citas (Scopus)

Resumen

Peptide coassembly, wherein at least two different peptides interact to form multicomponent nanostructures, is an attractive approach for generating functional biomaterials. Current efforts seek to design pairs of peptides, A and B, that form nanostructures (e.g., β-sheets with ABABA-type β-strand patterning) while resisting self-assembly (e.g., AAAAA-type or BBBBB-type β-sheets). To confer coassembly behavior, most existing designs have been based on highly charged variants of known self-assembling peptides; like-charge repulsion limits self-assembly while opposite-charge attraction promotes coassembly. Recent analyses using solid-state NMR and coarse-grained simulations reveal that preconceived notions of structure and molecular organization are not always correct. This perspective highlights recent advances and key challenges to understanding and controlling peptide coassembly.

Idioma original	English
Páginas (desde-hasta)	13599-13609
Número de páginas	11
Publicación	Journal of Physical Chemistry B
Volumen	125
N.º	50
DOI	https://doi.org/10.1021/acs.jpcb.1c04873
Estado	Published - dic 23 2021

Nota bibliográfica

Publisher Copyright:
© 2021 American Chemical Society.

Financiación

This research was supported by funds from the National Science Foundation Grant CBET-1743432 and OAC-1931430.

Financiadores	Número del financiador
U.S. Department of Energy Chinese Academy of Sciences Guangzhou Municipal Science and Technology Project Oak Ridge National Laboratory Extreme Science and Engineering Discovery Environment National Science Foundation National Energy Research Scientific Computing Center National Natural Science Foundation of China	CBET-1743432, OAC-1931430
U.S. Department of Energy Chinese Academy of Sciences Guangzhou Municipal Science and Technology Project Oak Ridge National Laboratory Extreme Science and Engineering Discovery Environment National Science Foundation National Energy Research Scientific Computing Center National Natural Science Foundation of China

ASJC Scopus subject areas

Physical and Theoretical Chemistry
Surfaces, Coatings and Films
Materials Chemistry

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10.1021/acs.jpcb.1c04873

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title = "Engineering β-Sheet Peptide Coassemblies for Biomaterial Applications",

abstract = "Peptide coassembly, wherein at least two different peptides interact to form multicomponent nanostructures, is an attractive approach for generating functional biomaterials. Current efforts seek to design pairs of peptides, A and B, that form nanostructures (e.g., β-sheets with ABABA-type β-strand patterning) while resisting self-assembly (e.g., AAAAA-type or BBBBB-type β-sheets). To confer coassembly behavior, most existing designs have been based on highly charged variants of known self-assembling peptides; like-charge repulsion limits self-assembly while opposite-charge attraction promotes coassembly. Recent analyses using solid-state NMR and coarse-grained simulations reveal that preconceived notions of structure and molecular organization are not always correct. This perspective highlights recent advances and key challenges to understanding and controlling peptide coassembly.",

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AU - Robang, Alicia S.

AU - Lint, Annabelle H.

AU - Wang, Yiming

AU - Dong, Xin

AU - Xiao, Xingqing

AU - Seroski, Dillon T.

AU - Liu, Renjie

AU - Shao, Qing

AU - Hudalla, Gregory A.

AU - Hall, Carol K.

AU - Paravastu, Anant K.

PY - 2021/12/23

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N2 - Peptide coassembly, wherein at least two different peptides interact to form multicomponent nanostructures, is an attractive approach for generating functional biomaterials. Current efforts seek to design pairs of peptides, A and B, that form nanostructures (e.g., β-sheets with ABABA-type β-strand patterning) while resisting self-assembly (e.g., AAAAA-type or BBBBB-type β-sheets). To confer coassembly behavior, most existing designs have been based on highly charged variants of known self-assembling peptides; like-charge repulsion limits self-assembly while opposite-charge attraction promotes coassembly. Recent analyses using solid-state NMR and coarse-grained simulations reveal that preconceived notions of structure and molecular organization are not always correct. This perspective highlights recent advances and key challenges to understanding and controlling peptide coassembly.

AB - Peptide coassembly, wherein at least two different peptides interact to form multicomponent nanostructures, is an attractive approach for generating functional biomaterials. Current efforts seek to design pairs of peptides, A and B, that form nanostructures (e.g., β-sheets with ABABA-type β-strand patterning) while resisting self-assembly (e.g., AAAAA-type or BBBBB-type β-sheets). To confer coassembly behavior, most existing designs have been based on highly charged variants of known self-assembling peptides; like-charge repulsion limits self-assembly while opposite-charge attraction promotes coassembly. Recent analyses using solid-state NMR and coarse-grained simulations reveal that preconceived notions of structure and molecular organization are not always correct. This perspective highlights recent advances and key challenges to understanding and controlling peptide coassembly.

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Engineering β-Sheet Peptide Coassemblies for Biomaterial Applications

Resumen

Nota bibliográfica

Financiación

ASJC Scopus subject areas

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