Article Synopsis
- The study introduces a cutting-edge method combining synthetic biology and engineering to create engineered plant living materials (EPLMs) using 3D bioprinting techniques on tobacco BY-2 cells.
- The researchers developed custom granular hydrogel scaffolds that allow for precise spatial arrangement and genetic transformation of plant cells while promoting their growth and uptake of external DNA.
- The resulting EPLMs demonstrate unique structural and functional traits, such as distinct pigmentation patterns, showcasing the potential for advancements in sustainable and adaptive living materials.
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Article 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 custom-engineered granular hydrogel scaffolds. Our methodology involves the integration of biocompatible hydrogel microparticles (HMPs) primed for 3D bioprinting with capable of plant cell transfection, serving as the backbone for the simultaneous growth and transformation of tobacco BY-2 cells. This system facilitates the concurrent growth and genetic modification of tobacco BY-2 cells within our specially designed scaffolds. These scaffolds enable the cells to develop into predefined patterns while remaining conducive to the uptake of exogenous DNA. We showcase the versatility of this technology by fabricating EPLMs with unique structural and functional properties, exemplified by EPLMs exhibiting distinct pigmentation patterns. These patterns are achieved through the integration of the betalain biosynthetic pathway into tobacco BY-2 cells. Overall, our study represents a groundbreaking shift in the convergence of materials science and plant synthetic biology, offering promising avenues for the evolution of sustainable, adaptive, and responsive living material systems.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11117683 | PMC |
| http://dx.doi.org/10.1021/acscentsci.4c00338 | DOI Listing |
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