Engineered cell‐to‐cell signalling within growing bacterial cellulose pellicles

Walker, Kenneth T.; Goosens, Vivianne J.; Das, Akashaditya; Graham, Alicia E.; Ellis, Tom

doi:10.1111/1751-7915.13340

Cited by 33 publications

(34 citation statements)

References 25 publications

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“…These studies together give a comprehensive guide for the construction of vectors of a high potential to be effective in the numerous species from this genus. These recent achievements include the use of quorum sensing (QS) synthetic biology elements known to be functional in E. coli (Florea et al 2016;Walker et al 2018). The first example of employment of these elements was the application of inducible lux promoter and luxR gene for modification of K. rhaeticus strain (Florea et al 2016).…”

Section: Molecular and Synthetic Biology Tools For Targeted Strain Mamentioning

confidence: 99%

“…This study showed that the capability of cellulose production was lowered and eventually switched off with increasing concentration of N-acyl homoserine lactone (AHL) in the media. Another study reported the construction of Sender and Receiver recombinant K. rhaeticus strains (Walker et al 2018). The first strain produced AHL in response to an environmental signal, while the second strain induced recombinant protein expression (red fluorescent protein, RFP) in response to AHL in a concentration-dependent manner.…”

Section: Molecular and Synthetic Biology Tools For Targeted Strain Mamentioning

confidence: 99%

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Towards control of cellulose biosynthesis by Komagataeibacter using systems-level and strain engineering strategies: current progress and perspectives

Ryngajłło

Jędrzejczak-Krzepkowska

Kubiak

et al. 2020

Appl Microbiol Biotechnol

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The strains of the Komagataeibacter genus have been shown to be the most efficient bacterial nanocellulose producers. Although exploited for many decades, the studies of these species focused mainly on the optimisation of cellulose synthesis process through modification of culturing conditions in the industrially relevant settings. Molecular physiology of Komagataeibacter was poorly understood and only a few studies explored genetic engineering as a strategy for strain improvement. Only since recently the systemic information of the Komagataeibacter species has been accumulating in the form of omics datasets representing sequenced genomes, transcriptomes, proteomes and metabolomes. Genetic analyses of the mutants generated in the untargeted strain modification studies have drawn attention to other important proteins, beyond those of the core catalytic machinery of the cellulose synthase complex. Recently, modern molecular and synthetic biology tools have been developed which showed the potential for improving targeted strain engineering. Taking the advantage of the gathered knowledge should allow for better understanding of the genotype-phenotype relationship which is necessary for robust modelling of metabolism as well as selection and testing of new molecular engineering targets. In this review, we discuss the current progress in the area of Komagataeibacter systems biology and its impact on the research aimed at scaled-up cellulose synthesis as well as BNC functionalisation. Key points • The accumulated omics datasets advanced the systemic understanding of Komagataeibacter physiology at the molecular level. • Untargeted and targeted strain modification approaches have been applied to improve nanocellulose yield and properties. • The development of modern molecular and synthetic biology tools presents a potential for enhancing targeted strain engineering. • The accumulating omic information should improve modelling of Komagataeibacter's metabolism as well as selection and testing of new molecular engineering targets.

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Section: Molecular and Synthetic Biology Tools For Targeted Strain Mamentioning

confidence: 99%

Section: Molecular and Synthetic Biology Tools For Targeted Strain Mamentioning

confidence: 99%

Towards control of cellulose biosynthesis by Komagataeibacter using systems-level and strain engineering strategies: current progress and perspectives

Ryngajłło

Jędrzejczak-Krzepkowska

Kubiak

et al. 2020

Appl Microbiol Biotechnol

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“…A follow-up paper from the same team later showed that induction of gene expression from plasmids in these cells could be directed by the presence of other engineered cells grown in co-culture [45]. Strains engineered in Florea et al (2016) to respond to the AHL inducer and produce red fluorescent protein (RFP) were partnered with new strains engineered to constitutively express an enzyme (LuxI) that synthesizes AHL [46].…”

Section: Synthetic Biology Toolkits For Bringing New Functionality Tomentioning

confidence: 99%

“…These new strains (known as 'sender' cells) secrete AHL molecules into the media and when they are at high concentration and close proximity to the AHL-controlled cells ('receiver cells') they trigger them to produce RFP. The authors showed that these two cells could be co-cultured to grow BC pellicles that trigger their own red fluorescence and more importantly could be used to grow materials that self-sense the boundaries engineered cell populations and trigger gene expression only at these sites [45]. This foundational advance holds future promise for growing BC-based materials with genetically-encoded self-patterning.…”

Section: Synthetic Biology Toolkits For Bringing New Functionality Tomentioning

confidence: 99%

Engineering Bacterial Cellulose by Synthetic Biology

Singh

Walker

Ledesma-Amaro

et al. 2020

IJMS

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Synthetic biology is an advanced form of genetic manipulation that applies the principles of modularity and engineering design to reprogram cells by changing their DNA. Over the last decade, synthetic biology has begun to be applied to bacteria that naturally produce biomaterials, in order to boost material production, change material properties and to add new functionalities to the resulting material. Recent work has used synthetic biology to engineer several Komagataeibacter strains; bacteria that naturally secrete large amounts of the versatile and promising material bacterial cellulose (BC). In this review, we summarize how genetic engineering, metabolic engineering and now synthetic biology have been used in Komagataeibacter strains to alter BC, improve its production and begin to add new functionalities into this easy-to-grow material. As well as describing the milestone advances, we also look forward to what will come next from engineering bacterial cellulose by synthetic biology.

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“…Florea et al genetically engineered a BC-producing strain so that cellulose production and red fluorescent protein (RFP) production could be controlled by the addition of a small molecule inducer, which allowed for spatial patterning of the cellulose pellicle ( 35 ). Walker et al genetically engineered “sender” and “receiver” strains of a BC-producing bacteria to achieve boundary detection in a fused pellicle ( 36 ). Even with encouraging early efforts in this area, the potential functionality of smart ELMs composed of BC is limited by our ability to engineer BC-producing bacteria to secrete recombinant proteins and sense specific external cues.…”

Section: Introductionmentioning

confidence: 99%

Hybrid Living Capsules Autonomously Produced by Engineered Bacteria

Birnbaum

Manjula-Basavanna

Kan

et al. 2020

Preprint

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Bacterial cellulose (BC) has excellent material properties and can be produced cheaply and sustainably through simple bacterial culture, but BC-producing bacteria lack the extensive genetic toolkits of model organisms such as Escherichia coli. Here, we describe a simple approach for producing highly programmable BC materials through incorporation of engineered E. coli. The acetic acid bacterium Gluconacetobacter hansenii was co-cultured with engineered E. coli in droplets of glucose-rich media to produce robust cellulose capsules, which were then colonized by the E. coli upon transfer to selective lysogeny broth media. We show that the encapsulated E. coli can produce engineered protein nanofibers within the cellulose matrix, yielding hybrid capsules capable of sequestering specific biomolecules from the environment and enzymatic catalysis. Furthermore, we produced capsules capable of altering their own bulk physical properties through enzyme-induced biomineralization. This novel system, based on autonomous biological fabrication, significantly expands the functionality of BC-based living materials.

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Engineered cell‐to‐cell signalling within growing bacterial cellulose pellicles

Cited by 33 publications

References 25 publications

Towards control of cellulose biosynthesis by Komagataeibacter using systems-level and strain engineering strategies: current progress and perspectives

Towards control of cellulose biosynthesis by Komagataeibacter using systems-level and strain engineering strategies: current progress and perspectives

Engineering Bacterial Cellulose by Synthetic Biology

Hybrid Living Capsules Autonomously Produced by Engineered Bacteria

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