Engineering cyanobacteria for the production of aromatic natural products

Gu, Fei; Li, Chaofeng; Zheng, Haotian; Ni, Jun

doi:10.1186/s44315-024-00002-w

Blue Biotechnology

2024

DOI: 10.1186/s44315-024-00002-w

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Engineering cyanobacteria for the production of aromatic natural products

Fei Gu,

Chaofeng Li,

Haotian Zheng

et al.

Abstract: Aromatic natural products are important for improving human health and quality of life. Large-scale availability of these compounds from plants is limited by low yield and cumbersome extraction. Building high-performance microbial cell factories to produce aromatic natural products by means of metabolic engineering and synthetic biology is a viable option. In the context of climate change and global resource scarcity, choosing solar-powered and carbon-fixing microbial cyanobacteria instead of chemical heterotr… Show more

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Cited by 3 publications

References 131 publications

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Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Li,

Wang,

et al. 2024

Metabolic Engineering

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Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Li,

Wang,

et al. 2024

Metabolic Engineering

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Extended Toolboxes Enable Efficient Biosynthesis of Multiple Products from CO₂ in Fast-Growing Synechococcus sp. PCC 11901

Zhang,

Li,

Chen

et al. 2024

ACS Sustainable Chem. Eng.

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Cyanobacteria are known to be photoautotrophic cell factories capable of converting CO 2 into valuable chemicals. The newly discovered marine cyanobacterium Synechococcus sp. PCC 11901 (hereafter PCC 11901) offers several advantages like rapid growth, high biomass, and high salinity tolerance, representing a promising chassis. To promote its application, we developed genetic toolboxes applicable to PCC 11901 in this study. First, a cobalamin (V B12 )-independent chassis was constructed, allowing for cheaper cultivation. Second, genome copy numbers and transformation methods were, respectively, measured and optimized. Then, 14 neutral sites were identified and characterized within the genome PCC 11901, providing locations for genetic integration of exogenous cassettes. Subsequently, promoter libraries were developed, reaching an expression range of approximately 800 folds for constitutive promoters and an induction fold of up to approximately 400 for inducible promotors, respectively. As a proof of concept, natural production of the total lipid and phycocyanin was investigated using V B12 -independent chassis, which realized an increase of 14.91% with lipid content compared with that of the wild-type strain. Further, we engineered the synthetic pathways of glucosylglycerol (GG) into PCC 11901 using the established toolboxes, reaching 590.41 ± 21.48 mg/L for GG production and self-sedimentation in photoreactors with the highest OD 750 nm at 17.57 ± 0.77. Finally, the GG-producing strain grew well in seawater, reaching 324.50 ± 5.34 mg/L in shaking flask, which provided new strategies for cyanobacteria cultivation and production. Our work here made it possible to develop the fast-growing PCC 11901 as efficient carbon-neutral cell factory in the future.

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Complete Epoxy Phosphonate Conversion to Dimethyl (1E)-3-Hydroxyprop-1-Enylphosphonate with Photobiocatalysts’ Assistance

Samson,

Serafin-Lewańczuk,

Brzezińska-Rodak

et al. 2024

Symmetry

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Phosphonates derivatives are compounds of interests and are applied as drugs of, e.g., antibacterial antiviral activities, connected with their inhibitory activity towards different enzymes, which is related to the configuration of particular compound isomers. The biological synthesis of such molecules is the method of choice and can be carried out using enzymes or whole cells from organisms. Photobiocatalysts employed in the bioconversion of epoxymethyl dimethyl phosphonate are able to convert this substrate into a pure geometric isomer of the unsaturated product, dimethyl (1E)-3-hydroxyprop-1-enylphosphonate, which is a rare and expensive compound of high added value. Six different strains were screened towards dimethyl epoxy phosphonate and in the case of Synechococcus bigranulatus, over 99% conversion was achieved. The product structure was confirmed with Mass Spectroscopy (MS); 1H, 13C, 31P, and 2D Nuclear Magnetic Resonance (NMR); and Infrared Spectroscopy (IR).

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Engineering cyanobacteria for the production of aromatic natural products

Cited by 3 publications

References 131 publications

Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Extended Toolboxes Enable Efficient Biosynthesis of Multiple Products from CO₂ in Fast-Growing Synechococcus sp. PCC 11901

Complete Epoxy Phosphonate Conversion to Dimethyl (1E)-3-Hydroxyprop-1-Enylphosphonate with Photobiocatalysts’ Assistance

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Engineering cyanobacteria for the production of aromatic natural products

Cited by 3 publications

References 131 publications

Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Engineering Metabolic Flux for the Microbial Synthesis of Aromatic Compounds

Extended Toolboxes Enable Efficient Biosynthesis of Multiple Products from CO2 in Fast-Growing Synechococcus sp. PCC 11901

Complete Epoxy Phosphonate Conversion to Dimethyl (1E)-3-Hydroxyprop-1-Enylphosphonate with Photobiocatalysts’ Assistance

Contact Info

Product

Resources

About

Extended Toolboxes Enable Efficient Biosynthesis of Multiple Products from CO₂ in Fast-Growing Synechococcus sp. PCC 11901