De novo biosynthesis of 3-hydroxy-3-methylbutyrate as anti-catabolic supplement by metabolically engineered Escherichia coli.

3-Hydroxy-3-methylbutyrate (HMB) is a five-carbon branch-chain hydroxy acid currently used as a dietary supplement to treat sarcopenia and exercise training. However, its current production relies on conventional chemical processes which require toxic substances and are generally non-sustainable. While bio-based syntheses of HMB have been developed, they are dependent on biotransformation of its direct precursors which are generally costly.

Metabolic Engineering Design Strategies for Increasing Carbon Fluxes Relevant for Biosynthesis in Cyanobacteria.

Cyanobacteria are promising microbial cell factories for the direct production of biochemicals and biofuels from CO. Through genetic and metabolic engineering, they can be modified to produce a variety of both natural and non-natural compounds. To enhance the yield of these products, various design strategies have been developed.

Metabolic engineering of Escherichia coli for efficient biosynthesis of butyl acetate.

Background: Butyl acetate is a versatile compound that is widely used in the chemical and food industry. The conventional butyl acetate synthesis via Fischer esterification of butanol and acetic acid using catalytic strong acids under high temperature is not environmentally benign. Alternative lipase-catalyzed ester formation requires a significant amount of organic solvent which also presents another environmental challenge.

Metabolic Engineering Design Strategies for Increasing Acetyl-CoA Flux.

Acetyl-CoA is a key metabolite precursor for the biosynthesis of lipids, polyketides, isoprenoids, amino acids, and numerous other bioproducts which are used in various industries. Metabolic engineering efforts aim to increase carbon flux towards acetyl-CoA in order to achieve higher productivities of its downstream products. In this review, we summarize the strategies that have been implemented for increasing acetyl-CoA flux and concentration, and discuss their effects.

Chemical Production from Methanol Using Natural and Synthetic Methylotrophs.

Methanol as a chemical feedstock is becoming increasingly important as it is derived from natural gas and is a feasible end-product for captured carbon dioxide. Biological conversion of methanol through natural and synthetic methylotrophs increases the chemical repertoire and is an important direction for one carbon (C1) based chemical economy. Advances in the metabolic engineering and synthetic biology enable development of microbial cell factories for converting methanol into various platform chemicals.