Engineered Living Materials Grown from Programmable Mycelial Pellets

Overview

Journal Mater Today Bio

Specialty Biomedical Engineering

Date 2023 Feb 16

PMID 36793323

Authors

Ke Li

Zhen Wei

Jianyao Jia

Qing Xu

Hao Liu

Chao Zhong

He Huang

Affiliations

Soon will be listed here.

Abstract

The development of engineered living materials (ELMs) has recently attracted significant attention from researchers across multiple disciplines. Fungi-derived ELMs represent a new type of macroscale, cost-effective, environmentally sustainable materials. However, current fungi-based ELMs either have to undergo a final process to heat-kill the living cells or rely on the co-culture with a model organism for functional modification, which hinders the engineerability and versatility of these materials. In this study, we report a new type of ELMs - grown from programmable mycelial pellets - by a simple filtration step under ambient conditions. We demonstrate that pellets can provide sufficient cohesion to maintain large-area self-supporting structures even under low pH conditions. Subsequently, by tuning the inducible expression of genes involved in melanin biosynthesis, we verified the fabrication of self-supporting living membrane materials with tunable colors in response to xylose concentration in the surroundings, which can be further explored as a potential biosensor for detecting xylose level in industrial wastewater. Notably, the living materials remain alive, self-regenerative, and functional even after 3-month storage. Thus, beyond reporting a new engineerable fungi chassis for constructing ELMs, our study provides new opportunities for developing bulk living materials for real-world applications such as the production of fabrics, packaging materials, and biosensors.

Citing Articles

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Harnessing Fungi Signaling in Living Composites.

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