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Metabolic Engineering of <i>Saccharomyces cerevisiae</i> for Fermentative Production of Heme

Hyun‐Jae Lee, Dong Joo Shin, Soo Bin Nho, Ki Won Lee, Sun‐Ki Kim

2024Biotechnology Journal16 citationsDOIOpen Access PDF

Abstract

Heme is a key ingredient required to mimic the color and flavor of meat in plant-based alternatives. This study aimed to develop a yeast-based microbial cell factory for efficient and sustainable production of heme. To this end, first, Hem12p (uroporphyrinogen decarboxylase) was identified as the rate-limiting enzyme in the heme biosynthetic pathway present in Saccharomyces cerevisiae D452-2. Next, we investigated the effects of disruption of the genes involved in the competition for heme biosynthesis precursors, transcriptional repression, and heme degradation (HMX1) on heme production efficiency. Of the knock-out strains constructed in this study, only the HMX1-deficient strain produced heme at a higher concentration than the background strain without gene disruption. In addition, overexpression of PUG1 encoding a plasma membrane transporter involved in protoporphyrin IX (the precursor to heme biosynthesis) uptake led to a significant increase in intracellular heme concentration. As a result, among the various engineered strains constructed in this study, the ΔHMX1/H3&12 + PUG1 strain, the HMX1-deficient strain overexpressing HEM3, HEM12, and PUG1, produced the highest concentration of heme (4.6 mg/L) in batch fermentation, which was 3.9-fold higher than that produced by the wild-type D452-2 strain. In a glucose-limited fed-batch fermentation, the ΔHMX1/H3&12 + PUG1 strain produced 28 mg/L heme in 66 h.

Topics & Concepts

HemeBiochemistrySaccharomyces cerevisiaeMetabolic engineeringChemistryStrain (injury)FermentationBiosynthesisHeme oxygenaseYeastEnzymeBiologyAnatomyPorphyrin Metabolism and DisordersEndoplasmic Reticulum Stress and DiseasePhotosynthetic Processes and Mechanisms