Examining Organic Acid Production Potential and Growth-coupled Strategies in Issatchenkia Orientalis Using Constraint-based Modeling

Overview

Journal Biotechnol Prog

Specialties Biomedical Engineering
Biotechnology

Date 2022 May 23

PMID 35603544

Authors

Patrick F Suthers

Costas D Maranas

Affiliations

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Abstract

Growth-coupling product formation can facilitate strain stability by aligning industrial objectives with biological fitness. Organic acids make up many building block chemicals that can be produced from sugars obtainable from renewable biomass. Issatchenkia orientalis is a yeast strain tolerant to acidic conditions and is thus a promising host for industrial production of organic acids. Here, we use constraint-based methods to assess the potential of computationally designing growth-coupled production strains for I. orientalis that produce 22 different organic acids under aerobic or microaerobic conditions. We explore native and engineered pathways using glucose or xylose as the carbon substrates as proxy constituents of hydrolyzed biomass. We identified growth-coupled production strategies for 37 of the substrate-product pairs, with 15 pairs achieving production for any growth rate. We systematically assess the strain design solutions and categorize the underlying principles involved.

Citing Articles

Examining organic acid production potential and growth-coupled strategies in Issatchenkia orientalis using constraint-based modeling.

Suthers P, Maranas C Biotechnol Prog. 2022; 38(5):e3276.

PMID: 35603544 PMC: 9786923. DOI: 10.1002/btpr.3276.

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