Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing

Lynn M. Sidor; Michelle M. Beaulieu; Ilia Rasskazov; B. Cansu Acarturk; Jie Ren; Emerson Jenen; Lycka Kamoen; María Vázquez Vitali; P. Scott Carney; Greg R. Schmidt; Wil V. Srubar; Elio A. Abbondanzieri; Anne S. Meyer

doi:10.1073/pnas.2409335121

Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing

Lynn M. Sidor
, Michelle M. Beaulieu
, Ilia Rasskazov
, B. Cansu Acarturk
, Jie Ren
, Emerson Jenen
, Lycka Kamoen
, María Vázquez Vitali
, P. Scott Carney
, Greg R. Schmidt
, Wil V. Srubar
, Elio A. Abbondanzieri
, Anne S. Meyer^*

^*Corresponding author for this work

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

2 Scopus citations

Abstract

Cutting-edge photonic devices frequently rely on microparticle components to focus and manipulate light. Conventional methods used to produce these microparticle components frequently offer limited control of their structural properties or require low-throughput nanofabrication of more complex structures. Here, we employ a synthetic biology approach to produce environmentally friendly, living microlenses with tunable structural properties. We engineered Escherichia coli bacteria to display the silica biomineralization enzyme silicatein from aquatic sea sponges. Our silicatein-expressing bacteria can self-assemble a shell of polysilicate “bioglass” around themselves. Remarkably, the polysilicate-encapsulated bacteria can focus light into intense nanojets that are nearly an order of magnitude brighter than unmodified bacteria. Polysilicate-encapsulated bacteria are metabolically active for up to 4 mo, potentially allowing them to sense and respond to stimuli over time. Our data demonstrate that synthetic biology offers a pathway for producing inexpensive and durable photonic components that exhibit unique optical properties.

Original language	English
Article number	e2409335121
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	121
Issue number	51
DOIs	https://doi.org/10.1073/pnas.2409335121
State	Published - 17 Dec 2024
Externally published	Yes

Bibliographical note

Publisher Copyright:
Copyright © 2024 the Author(s). Published by PNAS. This article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

bioglass
engineered living materials
photonic nanojets
silicatein
synthetic biology

ASJC Scopus subject areas

General

Access to Document

10.1073/pnas.2409335121

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Sidor, L. M., Beaulieu, M. M., Rasskazov, I., Cansu Acarturk, B., Ren, J., Jenen, E., Kamoen, L., Vitali, M. V., Scott Carney, P., Schmidt, G. R., Srubar, W. V., Abbondanzieri, E. A., & Meyer, A. S. (2024). Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing. Proceedings of the National Academy of Sciences of the United States of America, 121(51), Article e2409335121. https://doi.org/10.1073/pnas.2409335121

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title = "Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing",

abstract = "Cutting-edge photonic devices frequently rely on microparticle components to focus and manipulate light. Conventional methods used to produce these microparticle components frequently offer limited control of their structural properties or require low-throughput nanofabrication of more complex structures. Here, we employ a synthetic biology approach to produce environmentally friendly, living microlenses with tunable structural properties. We engineered Escherichia coli bacteria to display the silica biomineralization enzyme silicatein from aquatic sea sponges. Our silicatein-expressing bacteria can self-assemble a shell of polysilicate “bioglass” around themselves. Remarkably, the polysilicate-encapsulated bacteria can focus light into intense nanojets that are nearly an order of magnitude brighter than unmodified bacteria. Polysilicate-encapsulated bacteria are metabolically active for up to 4 mo, potentially allowing them to sense and respond to stimuli over time. Our data demonstrate that synthetic biology offers a pathway for producing inexpensive and durable photonic components that exhibit unique optical properties.",

keywords = "bioglass, engineered living materials, photonic nanojets, silicatein, synthetic biology",

author = "Sidor, \{Lynn M.\} and Beaulieu, \{Michelle M.\} and Ilia Rasskazov and \{Cansu Acarturk\}, B. and Jie Ren and Emerson Jenen and Lycka Kamoen and Vitali, \{Mar{\'i}a V{\'a}zquez\} and \{Scott Carney\}, P. and Schmidt, \{Greg R.\} and Srubar, \{Wil V.\} and Abbondanzieri, \{Elio A.\} and Meyer, \{Anne S.\}",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 the Author(s). Published by PNAS. This article is distributed under Creative Commons Attribution-NonCommercial-NoDerivatives License 4.0 (CC BY-NC-ND).",

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doi = "10.1073/pnas.2409335121",

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Sidor, LM, Beaulieu, MM, Rasskazov, I, Cansu Acarturk, B, Ren, J, Jenen, E, Kamoen, L, Vitali, MV, Scott Carney, P, Schmidt, GR, Srubar, WV, Abbondanzieri, EA & Meyer, AS 2024, 'Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing', Proceedings of the National Academy of Sciences of the United States of America, vol. 121, no. 51, e2409335121. https://doi.org/10.1073/pnas.2409335121

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T1 - Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing

AU - Sidor, Lynn M.

AU - Beaulieu, Michelle M.

AU - Rasskazov, Ilia

AU - Cansu Acarturk, B.

AU - Ren, Jie

AU - Jenen, Emerson

AU - Kamoen, Lycka

AU - Vitali, María Vázquez

AU - Scott Carney, P.

AU - Schmidt, Greg R.

AU - Srubar, Wil V.

AU - Abbondanzieri, Elio A.

AU - Meyer, Anne S.

PY - 2024/12/17

Y1 - 2024/12/17

N2 - Cutting-edge photonic devices frequently rely on microparticle components to focus and manipulate light. Conventional methods used to produce these microparticle components frequently offer limited control of their structural properties or require low-throughput nanofabrication of more complex structures. Here, we employ a synthetic biology approach to produce environmentally friendly, living microlenses with tunable structural properties. We engineered Escherichia coli bacteria to display the silica biomineralization enzyme silicatein from aquatic sea sponges. Our silicatein-expressing bacteria can self-assemble a shell of polysilicate “bioglass” around themselves. Remarkably, the polysilicate-encapsulated bacteria can focus light into intense nanojets that are nearly an order of magnitude brighter than unmodified bacteria. Polysilicate-encapsulated bacteria are metabolically active for up to 4 mo, potentially allowing them to sense and respond to stimuli over time. Our data demonstrate that synthetic biology offers a pathway for producing inexpensive and durable photonic components that exhibit unique optical properties.

AB - Cutting-edge photonic devices frequently rely on microparticle components to focus and manipulate light. Conventional methods used to produce these microparticle components frequently offer limited control of their structural properties or require low-throughput nanofabrication of more complex structures. Here, we employ a synthetic biology approach to produce environmentally friendly, living microlenses with tunable structural properties. We engineered Escherichia coli bacteria to display the silica biomineralization enzyme silicatein from aquatic sea sponges. Our silicatein-expressing bacteria can self-assemble a shell of polysilicate “bioglass” around themselves. Remarkably, the polysilicate-encapsulated bacteria can focus light into intense nanojets that are nearly an order of magnitude brighter than unmodified bacteria. Polysilicate-encapsulated bacteria are metabolically active for up to 4 mo, potentially allowing them to sense and respond to stimuli over time. Our data demonstrate that synthetic biology offers a pathway for producing inexpensive and durable photonic components that exhibit unique optical properties.

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KW - engineered living materials

KW - photonic nanojets

KW - silicatein

KW - synthetic biology

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JO - Proceedings of the National Academy of Sciences of the United States of America

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M1 - e2409335121

ER -

Engineered bacteria that self-assemble bioglass polysilicate coatings display enhanced light focusing

Abstract

Bibliographical note

UN SDGs

Keywords

ASJC Scopus subject areas

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