Living materials with programmable functionalities grown from engineered microbial co-cultures

Gilbert, Charlie; Tang, Tzu‐Chieh; Ott, Wolfgang; Dorr, Brandon Arthur; Shaw, W. M.; Sun, George L.; Lu, Timothy K.

doi:10.1038/s41563-020-00857-5

Cited by 178 publications

(127 citation statements)

References 67 publications

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“…In addition to these natural polysaccharides, which have been used by humans for centuries, microbes can now be modified to produce engineered living materials with entirely new functions (Gilbert and Ellis, 2019). In a recent landmark study, cellulose functionalized with enzymes or optogenetic sensors was produced by the co-culture of Komagataeibacter rhaeticus bacteria and engineered yeast (Gilbert et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…Greater interest in the engineering of polysaccharide-based biomaterials has emerged in recent years. Synthetic biology efforts in this area have been largely restricted to bacterial cellulose due to its well-characterized production (Gilbert and Ellis, 2019;Gilbert et al, 2021). Although suitable orthogonal hosts have been identified (Pauly et al, 2019), comparatively little is known about how the biosynthesis of plant hemicelluloses by glycosyltransferases (GTs) could be reconstituted and modulated in non-plant cell factories.…”

Section: Introductionmentioning

confidence: 99%

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Modular biosynthesis of plant hemicellulose and its impact on yeast cells

Robert

Waldhauer

Stritt

et al. 2021

Preprint

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Interest in the engineering of polysaccharide-based biomaterials has emerged in recent years. Despite impressive advances on bacterial cellulose, comparatively little is known about how plant hemicelluloses can be reconstituted and modulated in cells suitable for biotechnological purposes. Here, we optimized the cultivation of the yeast Pichia pastoris for the orthogonal production of plant polysaccharides, and enhanced heteromannan (HM) production by assembling modular cellulose synthase-like A (CSLA) enzymes. Chimeric proteins swapping the domains of a plant mannan synthase and a glucomannan synthase led, in three cases, to higher yields or improved growth compared to the parental CSLA enzymes. Prolonged expression of a glucomannan synthase from Amorphophallus konjac (AkCSLA3) was toxic to yeast cells, as demonstrated by reduced biomass accumulation and elevated uptake of dyes that are normally restricted to the extracellular matrix. However, no growth inhibition was observed for CSLA variants producing relatively pure mannan or a CSLC glucan synthase. The toxicity of AkCSLA3 was reduced by swapping its C-terminal region with that of a mannan synthase. HM production was further boosted by co-expressing chimeric CSLA proteins with the MANNAN-SYNTHESIS-RELATED1 (MSR1) putative glycosyltransferase. Interestingly, Pichia cells either increased or decreased in size depending on the CSLA variant expressed, and most of them remained viable even producing copious amounts of hemicellulose. Therefore, yeast modified with non-toxic plant polysaccharides could represent a modular chassis to produce and protect sensitive cargo such as therapeutic proteins.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modular biosynthesis of plant hemicellulose and its impact on yeast cells

Robert

Waldhauer

Stritt

et al. 2021

Preprint

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“…Engineering biology is exploding with advances ranging from new genome editing tools (1), to genetically encodable materials for advanced sensing of cells physiological states, electrical fields and mechanical stresses (2, 3), programmable and functional microbial-based living materials (4), environmental remediation and pollution control (5) to advanced in vivo data storage (6). Moreover, these advances in fundamental science are rapidly translating into new companies (7) and consumer products (8), which within the first half of this century, are set to impact most areas of our lives.…”

Section: Main Textmentioning

confidence: 99%

Versioning Biological Cells for Trustworthy Cell Engineering

Tellechea‐Luzardo

Velázquez

et al. 2021

Preprint

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Abstract“Full-stack”biotechnology platforms for cell line (re)programming are on the horizon, due mostly to (a) advances in gene synthesis and editing techniques as well as (b) the growing integration with informatics, the internet of things and automation. These emerging platforms will accelerate the production and consumption of biological products. Hence, transparency, traceability and -ultimately-trustworthiness is required -from cradle to grave- for engineered cell lines and their engineering processes. We report here the first version control system for cell engineering that integrates a new cloud-based version control software for cell lines’ digital footprint with molecular barcoding of living samples. We argue that version control for cell engineering marks a significant step towards more open, reproducible, easier to trace and share, and more trustworthy engineering biology.One Sentence SummaryWe demonstrate a transparent and open way of engineering and sharing cell lines.

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“…[1][2][3] The emerging field of living materials has leveraged microbial engineering to produce materials for various applications, but building 3D structures in arbitrary patterns and shapes has been a major challenge. [1][2][3][4][5][6][7][8][9][10][11][12][13][14] We set out to develop a new bioink, termed as "microbial ink" that is produced entirely from genetically engineered microbial cells, programmed to perform a bottom-up, hierarchical self-assembly of protein monomers into nanofibers, and further into nanofiber networks that comprise extrudable hydrogels. We further demonstrate the 3D printing of functional living materials by embedding programmed Escherichia coli (E. coli) cells and nanofibers into microbial ink, which can sequester toxic moieties, release biologics and regulate its own cell growth through the chemical induction of rationally designed genetic circuits.…”

Section: Living Cells Have the Capability To Synthesize Molecular Components And Preciselymentioning

confidence: 99%

Programmable Microbial Ink for 3D Printing of Living Materials Produced from Genetically Engineered Protein Nanofibers

Duraj-Thatte

Manjula-Basavanna

Rutledge

et al. 2021

Preprint

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Living cells have the capability to synthesize molecular components and precisely assemble them from the nanoscale to build macroscopic living functional architectures under ambient conditions. The emerging field of living materials has leveraged microbial engineering to produce materials for various applications, but building 3D structures in arbitrary patterns and shapes has been a major challenge. We set out to develop a new bioink, termed as "microbial ink" that is produced entirely from genetically engineered microbial cells, programmed to perform a bottom-up, hierarchical self-assembly of protein monomers into nanofibers, and further into nanofiber networks that comprise extrudable hydrogels. We further demonstrate the 3D printing of functional living materials by embedding programmed Escherichia coli (E. coli) cells and nanofibers into microbial ink, which can sequester toxic moieties, release biologics and regulate its own cell growth through the chemical induction of rationally designed genetic circuits. This report showcases the advanced capabilities of nanobiotechnology and living materials technology to 3D-print functional living architectures.

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Living materials with programmable functionalities grown from engineered microbial co-cultures

Cited by 178 publications

References 67 publications

Modular biosynthesis of plant hemicellulose and its impact on yeast cells

Modular biosynthesis of plant hemicellulose and its impact on yeast cells

Versioning Biological Cells for Trustworthy Cell Engineering

Programmable Microbial Ink for 3D Printing of Living Materials Produced from Genetically Engineered Protein Nanofibers

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