Advancing Engineered Plant Living Materials through Tobacco BY-2 Cell Growth and Transfection within Tailored Granular Hydrogel Scaffolds

Wang, Yujie; Di, Zhengao; Qin, Minglang; Qu, Shenming; Zhong, Wenbo; Yuan, Lingfeng; Zhang, Jing; Hibberd, Julian M.; Yu, Ziyi

doi:10.1021/acscentsci.4c00338

ACS Cent. Sci.

2024

DOI: 10.1021/acscentsci.4c00338

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Advancing Engineered Plant Living Materials through Tobacco BY-2 Cell Growth and Transfection within Tailored Granular Hydrogel Scaffolds

Yujie Wang,

Zhengao Di,

Minglang Qin

et al.

Abstract: In this study, an innovative approach is presented in the field of engineered plant living materials (EPLMs), leveraging a sophisticated interplay between synthetic biology and engineering. We detail a 3D bioprinting technique for the precise spatial patterning and genetic transformation of the tobacco BY-2 cell line within customengineered granular hydrogel scaffolds. Our methodology involves the integration of biocompatible hydrogel microparticles (HMPs) primed for 3D bioprinting with Agrobacterium tumefacie… Show more

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2024

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Cited by 3 publications

References 34 publications

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On‐Chip Engineered Living Materials as Field‐Deployable Biosensing Laboratories for Multiplexed Detection

Xu,

Tian,

et al. 2024

Adv Funct Materials

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Engineered living materials (ELMs) harness engineered cells to fabricate functional materials with lifelike characteristics, offering unparalleled potential across various fields. Nonetheless, the deployment of ELM‐based biosensors beyond laboratory settings remains challenging. Herin, ELMs are explored as field‐deployable biosensing laboratories on a microfluidic chip (ELMlab‐on‐Chip) for the simultaneous detection of diverse analytes in the field. This approach engages a bottom‐up strategy that includes the molecular engineering of living biosensors, the construction of stimuli‐responsive ELMs, and the fabrication of an integrated biosensing device. Specifically, living biosensors are engineered with fine‐tuned sensitivity and response by designing chimeric receptors and precisely controlling receptor concentration. Integrating ionic and covalent cross‐linking strategies in manufacturing ELMs ensures good substance permeability and mechanical robustness. Moreover, a microfluidic chip is devised tailored for the orthogonally stimuli‐responsive ELMs, creating a spatially encoded sensor array with the output detected by a miniaturized smartphone‐based detection device. The integrated ELMlab‐on‐Chip platform has demonstrated its potential in the simultaneous analysis of multiple chemicals from a single environmental sample under field conditions, offering an effective strategy to expedite the real‐world application of living materials.

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On‐Chip Engineered Living Materials as Field‐Deployable Biosensing Laboratories for Multiplexed Detection

Xu,

Tian,

et al. 2024

Adv Funct Materials

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Modulating Microbial Materials - Engineering Bacterial Cellulose with Synthetic Biology

Malcı,

Li,

Kisseroudis

et al. 2024

ACS Synth. Biol.

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The fusion of synthetic biology and materials science offers exciting opportunities to produce sustainable materials that can perform programmed biological functions such as sensing and responding or enhance material properties through biological means. Bacterial cellulose (BC) is a unique material for this challenge due to its high-performance material properties and ease of production from culturable microbes. Research in the past decade has focused on expanding the benefits and applications of BC through many approaches. Here, we explore how the current landscape of BC-based biomaterials is being shaped by progress in synthetic biology. As well as discussing how it can aid production of more BC and BC with tailored material properties, we place special emphasis on the potential of using BC for engineered living materials (ELMs); materials of a biological nature designed to carry out specific tasks. We also explore the role of 3D bioprinting being used for BC-based ELMs and highlight specific opportunities that this can bring. As synthetic biology continues to advance, it will drive further innovation in BC-based materials and ELMs, enabling many new applications that can help address problems in the modern world, in both biomedicine and many other application fields.

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Designing with Printed Responsive Biomaterials: A Review

Mogas-Soldevila,

Zolotovsky

2024

3D Printing and Additive Manufacturing

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Advancing Engineered Plant Living Materials through Tobacco BY-2 Cell Growth and Transfection within Tailored Granular Hydrogel Scaffolds

Cited by 3 publications

References 34 publications

On‐Chip Engineered Living Materials as Field‐Deployable Biosensing Laboratories for Multiplexed Detection

On‐Chip Engineered Living Materials as Field‐Deployable Biosensing Laboratories for Multiplexed Detection

Modulating Microbial Materials - Engineering Bacterial Cellulose with Synthetic Biology

Designing with Printed Responsive Biomaterials: A Review

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