Controlled node growth on the surface of polymersomes†

Marjolaine Thomas; Spyridon Varlas; Thomas R. Wilks; Stephen D. P. Fielden; Rachel K. O'Reilly

doi:10.1039/d3sc05915d

Controlled node growth on the surface of polymersomes†

Marjolaine Thomas, Spyridon Varlas, Thomas R. Wilks, Stephen D. P. Fielden^*, Rachel K. O'Reilly^*

^*Corresponding author for this work

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

Abstract

Incorporating nucleobases into synthetic polymers has proven to be a versatile method for controlling self-assembly. The formation of strong directional hydrogen bonds between complementary nucleobases provides a driving force that permits access to complex particle morphologies. Here, nucleobase pairing was used to direct the formation and lengthening of nodes on the outer surface of vesicles formed from polymers (polymersomes) functionalised with adenine in their membrane-forming domains. Insertion of a self-assembling short diblock copolymer containing thymine into the polymersome membranes caused an increase in steric crowding at the hydrophilic/hydrophobic interface, which was relieved by initial node formation and subsequent growth. Nano-objects were imaged by (cryo-)TEM, which permitted quantification of node coverage and length. The ability to control node growth on the surface of polymersomes provides a new platform to develop higher-order nanomaterials with tailorable properties.

Original language	English
Journal	Chemical Science
Early online date	16 Feb 2024
DOIs	https://doi.org/10.1039/d3sc05915d
Publication status	E-pub ahead of print - 16 Feb 2024

Bibliographical note

Acknowledgments:
SDPF thanks the Leverhulme Trust for an Early Career Fellowship (ECF-2021-240). We are grateful to Dr Saskia Bakker for assistance with cryo-TEM analysis and the Advanced BioImaging Research Technology Platform, BBSRC ALERT14 award BB/M01228X/1 is thanked for supporting cryo-TEM characterisation. We are grateful to Dr Yujie Xie for assistance with confocal microscopy.

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10.1039/d3sc05915dLicence: Creative Commons: Attribution (CC BY)

Nanoscale Containers for Synthetic Membrane Trafficking
Fielden, S.
Leverhulme Trust
1/10/21 → 31/01/25
Project: Research

Cite this

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title = "Controlled node growth on the surface of polymersomes†",

abstract = "Incorporating nucleobases into synthetic polymers has proven to be a versatile method for controlling self-assembly. The formation of strong directional hydrogen bonds between complementary nucleobases provides a driving force that permits access to complex particle morphologies. Here, nucleobase pairing was used to direct the formation and lengthening of nodes on the outer surface of vesicles formed from polymers (polymersomes) functionalised with adenine in their membrane-forming domains. Insertion of a self-assembling short diblock copolymer containing thymine into the polymersome membranes caused an increase in steric crowding at the hydrophilic/hydrophobic interface, which was relieved by initial node formation and subsequent growth. Nano-objects were imaged by (cryo-)TEM, which permitted quantification of node coverage and length. The ability to control node growth on the surface of polymersomes provides a new platform to develop higher-order nanomaterials with tailorable properties.",

author = "Marjolaine Thomas and Spyridon Varlas and Wilks, {Thomas R.} and Fielden, {Stephen D. P.} and O'Reilly, {Rachel K.}",

note = "Acknowledgments: SDPF thanks the Leverhulme Trust for an Early Career Fellowship (ECF-2021-240). We are grateful to Dr Saskia Bakker for assistance with cryo-TEM analysis and the Advanced BioImaging Research Technology Platform, BBSRC ALERT14 award BB/M01228X/1 is thanked for supporting cryo-TEM characterisation. We are grateful to Dr Yujie Xie for assistance with confocal microscopy.",

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AU - Wilks, Thomas R.

AU - Fielden, Stephen D. P.

AU - O'Reilly, Rachel K.

N1 - Acknowledgments: SDPF thanks the Leverhulme Trust for an Early Career Fellowship (ECF-2021-240). We are grateful to Dr Saskia Bakker for assistance with cryo-TEM analysis and the Advanced BioImaging Research Technology Platform, BBSRC ALERT14 award BB/M01228X/1 is thanked for supporting cryo-TEM characterisation. We are grateful to Dr Yujie Xie for assistance with confocal microscopy.

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N2 - Incorporating nucleobases into synthetic polymers has proven to be a versatile method for controlling self-assembly. The formation of strong directional hydrogen bonds between complementary nucleobases provides a driving force that permits access to complex particle morphologies. Here, nucleobase pairing was used to direct the formation and lengthening of nodes on the outer surface of vesicles formed from polymers (polymersomes) functionalised with adenine in their membrane-forming domains. Insertion of a self-assembling short diblock copolymer containing thymine into the polymersome membranes caused an increase in steric crowding at the hydrophilic/hydrophobic interface, which was relieved by initial node formation and subsequent growth. Nano-objects were imaged by (cryo-)TEM, which permitted quantification of node coverage and length. The ability to control node growth on the surface of polymersomes provides a new platform to develop higher-order nanomaterials with tailorable properties.

AB - Incorporating nucleobases into synthetic polymers has proven to be a versatile method for controlling self-assembly. The formation of strong directional hydrogen bonds between complementary nucleobases provides a driving force that permits access to complex particle morphologies. Here, nucleobase pairing was used to direct the formation and lengthening of nodes on the outer surface of vesicles formed from polymers (polymersomes) functionalised with adenine in their membrane-forming domains. Insertion of a self-assembling short diblock copolymer containing thymine into the polymersome membranes caused an increase in steric crowding at the hydrophilic/hydrophobic interface, which was relieved by initial node formation and subsequent growth. Nano-objects were imaged by (cryo-)TEM, which permitted quantification of node coverage and length. The ability to control node growth on the surface of polymersomes provides a new platform to develop higher-order nanomaterials with tailorable properties.

U2 - 10.1039/d3sc05915d

DO - 10.1039/d3sc05915d

M3 - Article

SN - 2041-6520

JO - Chemical Science

JF - Chemical Science

ER -

Controlled node growth on the surface of polymersomes†

Abstract

Bibliographical note

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Nanoscale Containers for Synthetic Membrane Trafficking

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