Litcius/Paper detail

Computational biology predicts metabolic engineering targets for increased production of 103 valuable chemicals in yeast

Iván Domenzain, Yao Lü, Haoyu Wang, Junling Shi, Hongzhong Lu, Jens Nielsen

2025Proceedings of the National Academy of Sciences13 citationsDOIOpen Access PDF

Abstract

Development of efficient cell factories that can compete with traditional chemical production processes is complex and generally driven by case-specific strategies, based on the product and microbial host of interest. Despite major advancements in the field of metabolic modeling in recent years, prediction of genetic modifications for increased production remains challenging. Here, we present a computational pipeline that leverages the concept of protein limitations in metabolism for prediction of optimal combinations of gene engineering targets for enhanced chemical bioproduction. We used our pipeline for prediction of engineering targets for 103 different chemicals using Saccharomyces cerevisiae as a host. Furthermore, we identified sets of gene targets predicted for groups of multiple chemicals, suggesting the possibility of rational model-driven design of platform strains for diversified chemical production.

Topics & Concepts

BioproductionMetabolic engineeringSynthetic biologyPipeline (software)Biochemical engineeringSaccharomyces cerevisiaeComputational biologyProduction (economics)YeastComputer scienceSystems biologyRational designBiologyBiotechnologyGeneEngineeringGeneticsMacroeconomicsProgramming languageEconomicsMicrobial Metabolic Engineering and BioproductionBiofuel production and bioconversionViral Infectious Diseases and Gene Expression in Insects
Computational biology predicts metabolic engineering targets for increased production of 103 valuable chemicals in yeast | Litcius