Tee-Kheang Ng scite author profile

Organophosphate compounds (OPs) have been employed in the agricultural industry as pesticides and insecticides for several decades. Many of the methods used currently for the detoxification of OPs are harmful and possess serious environmental consequences. Therefore, utilizing enzymes for the detection and decontamination of OPs is gaining increasing attention as an efficient and clean bioremediation strategy. Microbial enzymes, such as OP hydrolases, OP acid anhydrolases or methyl parathion hydrolase (MPH), are potent agents for OP decontamination. Their biochemical properties and biotechnological applications are discussed in this review, including a discussion on methods that may be employed to immobilize such enzymes, and essential steps to generate reusable and affordable biocatalytic systems for use in bioremediation and biorestoration.

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Altering the substrate specificity of methyl parathion hydrolase with directed evolution

Gahan

Schenk

et al. 2015

Archives of Biochemistry and Biophysics

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Genetic Engineering of an Unconventional Yeast for Renewable Biofuel and Biochemical Production

Pratomo

et al. 2016

JoVE

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Yarrowia lipolytica is a non-pathogenic, dimorphic and strictly aerobic yeast species. Owing to its distinctive physiological features and metabolic characteristics, this unconventional yeast is not only a good model for the study of the fundamental nature of fungal differentiation but is also a promising microbial platform for biochemical production and various biotechnological applications, which require extensive genetic manipulations. However, genetic manipulations of Y. lipolytica have been limited due to the lack of an efficient and stable genetic transformation system as well as very high rates of non-homologous recombination that can be mainly attributed to the KU70 gene. Here, we report an easy and rapid protocol for the efficient genetic transformation and for gene deletion in Y. lipolytica Po1g. First, a protocol for the efficient transformation of exogenous DNA into Y. lipolytica Po1g was established. Second, to achieve the enhanced double-crossover homologous recombination rate for further deletion of target genes, the KU70 gene was deleted by transforming a disruption cassette carrying 1 kb homology arms. Third, to demonstrate the enhanced gene deletion efficiency after deletion of the KU70 gene, we individually deleted 11 target genes encoding alcohol dehydrogenase and alcohol oxidase using the same procedures on the KU70 knockout platform strain. It was observed that the rate of precise homologous recombination increased substantially from less than 0.5% for deletion of the KU70 gene in Po1g to 33%-71% for the single gene deletion of the 11 target genes in Po1g KU70Δ. A replicative plasmid carrying the hygromycin B resistance marker and the Cre/LoxP system was constructed, and the selection marker gene in the yeast knockout strains was eventually removed by expression of Cre recombinase to facilitate multiple rounds of targeted genetic manipulations. The resulting single-gene deletion mutants have potential applications in biofuel and biochemical production.

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Engineering Yarrowia lipolytica towards food waste bioremediation: Production of fatty acid ethyl esters from vegetable cooking oil

Ng¹,

Yu²,

Ling³

et al. 2020

Journal of Bioscience and Bioengineering

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Rewriting the Metabolic Blueprint: Advances in Pathway Diversification in Microorganisms

et al. 2018

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Living organisms have evolved over millions of years to fine tune their metabolism to create efficient pathways for producing metabolites necessary for their survival. Advancement in the field of synthetic biology has enabled the exploitation of these metabolic pathways for the production of desired compounds by creating microbial cell factories through metabolic engineering, thus providing sustainable routes to obtain value-added chemicals. Following the past success in metabolic engineering, there is increasing interest in diversifying natural metabolic pathways to construct non-natural biosynthesis routes, thereby creating possibilities for producing novel valuable compounds that are non-natural or without elucidated biosynthesis pathways. Thus, the range of chemicals that can be produced by biological systems can be expanded to meet the demands of industries for compounds such as plastic precursors and new antibiotics, most of which can only be obtained through chemical synthesis currently. Herein, we review and discuss novel strategies that have been developed to rewrite natural metabolic blueprints in a bid to broaden the chemical repertoire achievable in microorganisms. This review aims to provide insights on recent approaches taken to open new avenues for achieving biochemical production that are beyond currently available inventions.

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Tee-Kheang Ng

Organophosphate-degrading metallohydrolases: Structure and function of potent catalysts for applications in bioremediation

Altering the substrate specificity of methyl parathion hydrolase with directed evolution

Genetic Engineering of an Unconventional Yeast for Renewable Biofuel and Biochemical Production

Engineering Yarrowia lipolytica towards food waste bioremediation: Production of fatty acid ethyl esters from vegetable cooking oil

Rewriting the Metabolic Blueprint: Advances in Pathway Diversification in Microorganisms

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