A safe and sustainable bacterial cellulose nanofiber separator for lithium rechargeable batteries

Gwon, Hyeokjo; Park, Kitae; Chung, Soon‐Chun; Kim, Ryoung-Hee; Kang, Jin Kyu; Ji, Sang Min; Kim, Nag‐Jong; Lee, Sunghaeng; Ku, Jun-Hwan; Cheol, Eun; Park, Su‐Jin; Kim, Minsang; Shim, Woo Yong; Rhee, Hong Soon; Kim, Jae‐Young; Kim, Jieun; Kim, Tae Yong; Yamaguchi, Yoshitaka; Iwamuro, Ryo; Saito, Shunsuke; Kim, Hyung-Seok; Jung, In‐Sun; Park, Hyokeun; Lee, Chanhee; Lee, Seungyeon; Jeon, Woo Sung; Jang, Woo Dae; Kim, Hyun Uk; Lee, Sang Yup; Im, Dongmin; Doo, Seok‐Gwang; Lee, Sang Yoon; Lee, Hyun Chul; Park, Jin Hwan

doi:10.1073/pnas.1905527116

Cited by 66 publications

(49 citation statements)

References 31 publications

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“…Heterologous overexpression of two of these targets, glucose-6-phosphate isomerase (pgi) and phosphogluconate dehydrogenase (gnd) brought enhanced BNC production, which was 2-fold for the strain overexpressing the E. coli pgi gene. In another study of this team, exploiting this GEM and through simulated FBA, it was found that the inclusion of a reaction catalysed by phosphofructokinase (pfkA), which is absent in the Komagataeibacter spp., improves cellulose production rate and specific growth rate (discussed later; Gwon et al 2019).…”

Section: Genome-scale Metabolism Modellingmentioning

confidence: 99%

“…In both studies, the observed increase of cellulose production yield by the VHb+ strains was in the range of 1.5-to 1.7-fold. A more recent study involving K. xylinus DSM 2325 strain has shown that the reduction of gluconic acid production can be achieved through manipulation of regulatory proteins, besides the direct catabolic enzymes (Gwon et al 2019). This study generated a strain with reduced gluconic acid synthesis yield (39.2% in the mutant and 64.8% of glucose in the parental strain) after introduction of an additional copy of the crp (Crp/Fnr) gene, expressed from a plasmid, under the tac promoter control.…”

Section: Improvement In Cellulose Productivitymentioning

confidence: 99%

“…Induction of gene disruption through a homologous recombination was commonly performed with the use of non-replicating plasmid disruption cassette carriers, such as pUC19, pT7Blue, pET14 or pHSG399 (Table 4 ). At present, one can expect intensification of genetic engineering of different Komagataeibacter strains due to the progress in the application of three new vector backbones for endogenous and heterologous gene expression, namely pTI99, pTSa and pSEVA331Bb (Fang et al 2015 ; Florea et al 2016 ; Jacek et al 2018 , 2019b ; Gwon et al 2019 ). Moreover, the performance of various promoters, ribosome binding sites (RBS) and terminators has been characterised in the first two studies applying synthetic biology tools in Komagataeibacter hosts (Florea et al 2016 ; Teh et al 2019 ).…”

Section: Introductionmentioning

confidence: 99%

“…Genetic modification of the Komagataeibacter strains has been used to generate a few industrially relevant mutant strains with improved cellulose productivity. These improvements have been achieved either through metabolic pathway modulation (Shigematsu et al 2005 ; Kuo et al 2015 ; Gwon et al 2019 ) or heterologous gene expression (Setyawati et al 2007 ; Liu et al 2018b ; Jang et al 2019 ).…”

Section: Introductionmentioning

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: Genome-scale Metabolism Modellingmentioning

confidence: 99%

Section: Improvement In Cellulose Productivitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

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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“…BC has outstanding properties, such as high water retention value, surface area, crystallinity, biodegradability, biocompatibility, and high purity due to the absence of lignin and hemicellulose [3][4][5][6]. Due to these properties, BC has potential applications in the biomedical, cosmetic, automotive, packaging, health food, electrical, and sensor industries, with a rapidly increasing commercial value [7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Enhanced Production of Bacterial Cellulose in Komagataeibacter xylinus Via Tuning of Biosynthesis Genes with Synthetic RBS

Hur¹,

Choi²,

Kim³

et al. 2020

J. Microbiol. Biotechnol.

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Recently, two research groups reported on the development of genetic toolkits, including synthetic promoters, RBSs, and plasmids useful for tuning the expression of target genes in Komagataeibacter spp. [12, 13]. Through the Bacterial cellulose (BC) has outstanding physical and chemical properties, including high crystallinity, moisture retention, and tensile strength. Currently, the major producer of BC is Komagataeibacter xylinus. However, due to limited tools of expression, this host is difficult to engineer metabolically to improve BC productivity. In this study, a regulated expression system for K. xylinus with synthetic ribosome binding site (RBS) was developed and used to engineer a BC biosynthesis pathway. A synthetic RBS library was constructed using green fluorescent protein (GFP) as a reporter, and three synthetic RBSs (R4, R15, and R6) with different strengths were successfully isolated by fluorescence-activated cell sorting (FACS). Using synthetic RBS, we optimized the expression of three homologous genes responsible for BC production, pgm, galU, and ndp, and thereby greatly increased it under both static and shaking culture conditions. The final titer of BC under static and shaking conditions was 5.28 and 3.67 g/l, respectively. Our findings demonstrate that reinforced metabolic flux towards BC through quantitative gene expression represents a practical strategy for the improvement of BC productivity.

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Metabolic Engineering of Escherichia coli

Luo

Ahn

Chae

et al. 2021

Metabolic Engineering

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A safe and sustainable bacterial cellulose nanofiber separator for lithium rechargeable batteries

Cited by 66 publications

References 31 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

Enhanced Production of Bacterial Cellulose in Komagataeibacter xylinus Via Tuning of Biosynthesis Genes with Synthetic RBS

Metabolic Engineering of Escherichia coli

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