Inverse metabolic engineering based on metabonomics for efficient production of hydroxytyrosol by Saccharomyces cerevisiae.

Metabolic engineering provides a powerful approach to efficiently produce valuable compounds, with the aid of emerging gene editing tools and diverse metabolic regulation strategies. However, apart from the current known biochemical pathway information, a variety of unclear constraints commonly limited the optimization space of cell phenotype. Hydroxytyrosol is an important phenolic compound that serves various industries with prominent health-beneficial properties. In this study, the inverse metabolic engineering based on metabolome analysis was customized and implemented to disclose the hidden rate-limiting steps and thus to improve hydroxytyrosol production in Saccharomyces cerevisiae (S. cerevisiae). The potential rate-limiting steps involved three modules that were eliminated individually via reinforcing and balancing metabolic flow, optimizing cofactor supply, and weakening the competitive pathways. Ultimately, a 118.53 % improvement in hydroxytyrosol production (639.84 mg/L) was achieved by inverse metabolic engineering.

[Recent advances in metabolic engineering of microorganisms for production of tyrosol and its derivatives].

Tyrosol is a natural phenolic compound with antioxidant, anti-inflammatory and other biological activities, serving as an important precursor of high-value products such as hydroxytyrosol and salidroside. Therefore, the green and efficient biosynthesis of tyrosol and its derivatives has become a research hotspot in recent years. Building cell factories by metabolic engineering of microorganisms is a potential industrial production way, which has low costs and environmental friendliness. This paper introduces the biosynthesis pathway of tyrosol and presents the key regulated nodes in the de novo synthesis of tyrosol in Escherichia coli and Saccharomyces cerevisiae. In addition, this paper reviews the recent advances in metabolic engineering for the production of hydroxytyrosol and salidroside. This review can provide a reference for engineering the strains for the high-yield production of tyrosol and its derivatives.