Accessing Nature’s diversity through metabolic engineering and synthetic biology

King, Jason R.; Edgar, Steven; Qiao, Kangjian; Stephanopoulos, Gregory

doi:10.12688/f1000research.7311.1

Cited by 43 publications

(25 citation statements)

References 118 publications

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“…The explosion of BGC sequence information offers critical insights into how remarkably complex natural products covering vast biologically relevant chemical structure space are assembled from a limited set of simple building blocks [115]. BGCs generally encode two groups of biosynthetic enzymes – one group generates key biosynthetic precursors and assembles the core scaffold while the other group derivatizes the scaffolds [116].…”

Section: Combinatorial Biosynthesismentioning

confidence: 99%

“…alkylation, acylation, oxidation, glycosylation) of natural product scaffolds allows exploration of a defined chemical structure-function space. Naturally occurring and engineered P450s and glycosyltransferases exhibiting broad substrate specificities have been successfully employed for late-stage derivatization of terpenes, PKs and NRPs [115]. New sulfated glycopeptide congeners were obtained in vitro and in vivo by exploiting eDNA-derived sulfotransferases frequently associated with glycopeptide BGCs [120].…”

Section: Combinatorial Biosynthesismentioning

confidence: 99%

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Using natural products for drug discovery: the impact of the genomics era

Zhang

Qiao

Ang

et al. 2017

Expert Opinion on Drug Discovery

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Introduction Evolutionarily selected over billions of years for their interactions with biomolecules, natural products have been and continue to be a major source of pharmaceuticals. In the 1990s, pharmaceutical companies scaled down their natural product discovery programs in favor of synthetic chemical libraries due to major challenges such as high rediscovery rates, challenging isolation, and low production titers. Propelled by advances in DNA sequencing and synthetic biology technologies, insights into microbial secondary metabolism provided have inspired a number of strategies to address these challenges. Areas covered This review highlights the importance of genomics and metagenomics in natural product discovery, and provides an overview of the technical and conceptual advances that offer unprecedented access to molecules encoded by biosynthetic gene clusters. Expert opinion Genomics and metagenomics revealed nature’s remarkable biosynthetic potential and her vast chemical inventory that we can now prioritize and systematically mine for novel chemical scaffolds with desirable bioactivities. Coupled with synthetic biology and genome engineering technologies, significant progress has been made in identifying and predicting the chemical output of biosynthetic gene clusters, as well as in optimizing cluster expression in native and heterologous host systems for the production of pharmaceutically relevant metabolites and their derivatives.

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Section: Combinatorial Biosynthesismentioning

confidence: 99%

Section: Combinatorial Biosynthesismentioning

confidence: 99%

Using natural products for drug discovery: the impact of the genomics era

Zhang

Qiao

Ang

et al. 2017

Expert Opinion on Drug Discovery

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“…A key focus of a number of research programmes is the design of genetic constructs containing the information necessary to synthesize the product(s) of interest from specific substrate(s). Despite this effervescence in the knowledge of molecular microbial ecology and bioinformatics (King et al, 2016), the number of biochemicals (referred to here as a chemical produced by a living organism) made in recent years at pilot-industrial scale is very modest. A question arisescan biochemicals made from renewable sources replace chemicals (here the term is used to refer to molecules made in the chemical realm), particularly when large amounts are required such as in the world of commodities?…”

Section: Introductionmentioning

confidence: 99%

Twenty‐first‐century chemical odyssey: fuels versus commodities and cell factories versus chemical plants

Ramos

Duque

2019

Microbial Biotechnology

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Summary The harmful effects of pollution from the massive and widespread use of fossil fuels have led various organizations and governments to search for alternative energy sources. To address this, a new energy bioprocess is being developed that utilizes non‐edible lignocellulose – the only sustainable source of organic carbon in nature. In this mini‐review, we consider the potential use of synthetic biology to develop new‐to‐nature pathways for the biosynthesis of chemicals that are currently synthesized using classical industrial approaches. The number of industrial processes based on starch or lignocellulose is still very modest. Advances in the area require the development of more efficient approaches to deconstruct plant materials, better exploitation of the catalytic potential of prokaryotes and lower eukaryotes and the identification of new and useful genes for product synthesis. Further research and progress is urgently needed in order for government and industry to achieve the major milestone of transitioning 30% of the total industry to renewable sources by 2050.

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“…In recent years, significant and growing interest has emerged in the development of alternative, microbial production routes for aromatic chemicals from renewable, biomass‐derived substrates. Such efforts have been aided by advancements in metabolic engineering, protein engineering, and systems and synthetic biology, which continue to guide both rational and combinatorial approaches towards efficient biocatalyst development. As a result, the de novo biosynthesis of a diversity of different aromatic chemicals is now a reality, with applications that, like their petroleum‐derived counterparts, include bulk chemicals and plastics, specialty chemicals, flavors and fragrances, and pharmaceuticals and nutraceuticals (Fig.…”

Section: Introductionmentioning

confidence: 99%

Emerging tools, enabling technologies, and future opportunities for the bioproduction of aromatic chemicals

Machas

Kurgan

Jha

et al. 2018

J of Chemical Tech & Biotech

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Aromatic compounds, which are traditionally derived from petroleum feedstocks, represent a diverse class of molecules with a wide range of industrial and commercial applications. Significant progress has been made to alternatively and sustainably produce many aromatics from renewable substrates using microbial biocatalysts. While the construction of both natural and non‐natural pathways has expanded the number and diversity of aromatic bioproducts, pathway modularization in both single‐ and multi‐strain systems continues to support the enhancement of key production metrics towards economically‐viable levels. Emerging tools for implementing more precise metabolic control (e.g. CRISPRi, sRNA) as well as the engineering of novel high‐throughput screening platforms utilizing in vivo aromatic biosensors, meanwhile, continue to facilitate further optimization of both pathways and hosts. While product toxicity persists as a key challenge limiting the production of many aromatics, various successful strategies have been demonstrated towards improving tolerance, including via membrane and efflux pump engineering as well as by exploiting alternative production hosts. Finally, as a further step towards sustainable and economical aromatic bioproduction, non‐model substrates including lignin‐derived compounds continue to emerge as viable feedstocks. This review highlights recent and notable achievements related to such efforts while offering future outlooks towards engineering microbial cell factories for aromatic production. © 2018 Society of Chemical Industry

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Accessing Nature’s diversity through metabolic engineering and synthetic biology

Cited by 43 publications

References 118 publications

Using natural products for drug discovery: the impact of the genomics era

Using natural products for drug discovery: the impact of the genomics era

Twenty‐first‐century chemical odyssey: fuels versus commodities and cell factories versus chemical plants

Emerging tools, enabling technologies, and future opportunities for the bioproduction of aromatic chemicals

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