Leveraging the versatile properties of bacterial spores in materials

Likhitha Reddy Kummetha; Jeong Joo Oh; Franka H. van der Linden; Marie Eve Aubin-Tam

doi:10.1016/j.tibtech.2024.09.018

Leveraging the versatile properties of bacterial spores in materials

Likhitha Reddy Kummetha, Jeong Joo Oh^*, Franka H. van der Linden, Marie Eve Aubin-Tam

^*Corresponding author for this work

BN/Marie-Eve Aubin-Tam Lab

Research output: Contribution to journal › Review article › peer-review

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Abstract

Inspired by biological functions of living systems, researchers have engineered cells as independent functional materials or integrated them within a natural or synthetic matrix to create engineered living materials (ELMs). However, the ‘livingness’ of cells in such materials poses serious drawbacks, such as a short lifespan and the need for cold-chain logistics. Bacterial spores have emerged as a game changer to bypass these shortcomings as a result of their intrinsic dormancy and resistance against harsh conditions. Emerging synthetic biology tools tailored for engineering spores and better understanding of their physical properties have led to novel applications of spore-based materials. Here, we review recent advances in such materials and discuss future challenges for the development of time- and cost-efficient spore-based materials with high performance.

Original language	English
Pages (from-to)	812-825
Number of pages	14
Journal	Trends in Biotechnology
Volume	43
Issue number	4
DOIs	https://doi.org/10.1016/j.tibtech.2024.09.018
Publication status	Published - 2024

Keywords

Bacillus subtilis
bacterial spore
engineered living materials
functional materials
synthetic biology

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10.1016/j.tibtech.2024.09.018

PIIS0167779924002804Proof, 1.23 MBLicence: CC BY

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title = "Leveraging the versatile properties of bacterial spores in materials",

abstract = "Inspired by biological functions of living systems, researchers have engineered cells as independent functional materials or integrated them within a natural or synthetic matrix to create engineered living materials (ELMs). However, the {\textquoteleft}livingness{\textquoteright} of cells in such materials poses serious drawbacks, such as a short lifespan and the need for cold-chain logistics. Bacterial spores have emerged as a game changer to bypass these shortcomings as a result of their intrinsic dormancy and resistance against harsh conditions. Emerging synthetic biology tools tailored for engineering spores and better understanding of their physical properties have led to novel applications of spore-based materials. Here, we review recent advances in such materials and discuss future challenges for the development of time- and cost-efficient spore-based materials with high performance.",

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AU - Kummetha, Likhitha Reddy

AU - Oh, Jeong Joo

AU - van der Linden, Franka H.

AU - Aubin-Tam, Marie Eve

PY - 2024

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AB - Inspired by biological functions of living systems, researchers have engineered cells as independent functional materials or integrated them within a natural or synthetic matrix to create engineered living materials (ELMs). However, the ‘livingness’ of cells in such materials poses serious drawbacks, such as a short lifespan and the need for cold-chain logistics. Bacterial spores have emerged as a game changer to bypass these shortcomings as a result of their intrinsic dormancy and resistance against harsh conditions. Emerging synthetic biology tools tailored for engineering spores and better understanding of their physical properties have led to novel applications of spore-based materials. Here, we review recent advances in such materials and discuss future challenges for the development of time- and cost-efficient spore-based materials with high performance.

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Leveraging the versatile properties of bacterial spores in materials

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