Litcius/Paper detail

Modular optimization in metabolic engineering

Matthew Wong, Abinaya Badri, Christopher Gasparis, Georges Belfort, Mattheos Koffas

2021Critical Reviews in Biochemistry and Molecular Biology14 citationsDOI

Abstract

There is an increasing demand for bioproducts produced by metabolically engineered microbes, such as pharmaceuticals, biofuels, biochemicals and other high value compounds. In order to meet this demand, modular optimization, the optimizing of subsections instead of the whole system, has been adopted to engineer cells to overproduce products. Research into modularity has focused on traditional approaches such as DNA, RNA, and protein-level modularity of intercellular machinery, by optimizing metabolic pathways for enhanced production. While research into these traditional approaches continues, limitations such as scale-up and time cost hold them back from wider use, while at the same time there is a shift to more novel methods, such as moving from episomal expression to chromosomal integration. Recently, nontraditional approaches such as co-culture systems and cell-free metabolic engineering (CFME) are being investigated for modular optimization. Co-culture modularity looks to optimally divide the metabolic burden between different hosts. CFME seeks to modularly optimize metabolic pathways in vitro, both speeding up the design of such systems and eliminating the issues associated with live hosts. In this review we will examine both traditional and nontraditional approaches for modular optimization, examining recent developments and discussing issues and emerging solutions for future research in metabolic engineering.

Topics & Concepts

BioproductsMetabolic engineeringModularity (biology)Modular designSynthetic biologyBiochemical engineeringComputer scienceSystems biologyBiotechnologyComputational biologyBiologyEngineeringBiofuelGeneticsBiochemistryEnzymeOperating systemMicrobial Metabolic Engineering and BioproductionViral Infectious Diseases and Gene Expression in InsectsCRISPR and Genetic Engineering