Chemomechanical Communication between Liposomes Based on Enzyme Cascades

Yu Ching Tseng; Jiaqi Song; Jianhua Zhang; Ekta Shandilya; Ayusman Sen

doi:10.1021/jacs.4c03415

Chemomechanical Communication between Liposomes Based on Enzyme Cascades

Yu Ching Tseng, Jiaqi Song, Jianhua Zhang, Ekta Shandilya, Ayusman Sen

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

8 Scopus citations

Abstract

Communication between cells is crucial to the survival of both uni- and multicellular organisms. The primary mode of communication involves chemical cues. There is great current interest in mimicking this behavior in synthetic cells to understand the physical basis of intercellular communication and design collective functional behavior. Using liposomal cell mimics, we demonstrate how a chemical input can elicit a mechanical response (enhanced motility). We employed a single substrate to trigger enzyme cascade-induced control of the diffusion of up to three different liposome populations. Furthermore, substrate competition allows temporal control over enhanced diffusion. The use of enzyme cascades to propagate chemical signals provides a robust and efficient mechanism for diverse populations of protocells to coordinate their motion in response to signals from each other.

Original language	English (US)
Pages (from-to)	16097-16104
Number of pages	8
Journal	Journal of the American Chemical Society
Volume	146
Issue number	23
DOIs	https://doi.org/10.1021/jacs.4c03415
State	Published - Jun 12 2024

All Science Journal Classification (ASJC) codes

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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10.1021/jacs.4c03415

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abstract = "Communication between cells is crucial to the survival of both uni- and multicellular organisms. The primary mode of communication involves chemical cues. There is great current interest in mimicking this behavior in synthetic cells to understand the physical basis of intercellular communication and design collective functional behavior. Using liposomal cell mimics, we demonstrate how a chemical input can elicit a mechanical response (enhanced motility). We employed a single substrate to trigger enzyme cascade-induced control of the diffusion of up to three different liposome populations. Furthermore, substrate competition allows temporal control over enhanced diffusion. The use of enzyme cascades to propagate chemical signals provides a robust and efficient mechanism for diverse populations of protocells to coordinate their motion in response to signals from each other.",

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AU - Tseng, Yu Ching

AU - Song, Jiaqi

AU - Zhang, Jianhua

AU - Shandilya, Ekta

AU - Sen, Ayusman

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AB - Communication between cells is crucial to the survival of both uni- and multicellular organisms. The primary mode of communication involves chemical cues. There is great current interest in mimicking this behavior in synthetic cells to understand the physical basis of intercellular communication and design collective functional behavior. Using liposomal cell mimics, we demonstrate how a chemical input can elicit a mechanical response (enhanced motility). We employed a single substrate to trigger enzyme cascade-induced control of the diffusion of up to three different liposome populations. Furthermore, substrate competition allows temporal control over enhanced diffusion. The use of enzyme cascades to propagate chemical signals provides a robust and efficient mechanism for diverse populations of protocells to coordinate their motion in response to signals from each other.

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Chemomechanical Communication between Liposomes Based on Enzyme Cascades

Abstract

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