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Comparison of stress tolerance mechanisms between <i>Saccharomyces cerevisiae</i> and the multistress-tolerant <i>Pichia kudriavzevii</i>

Thasneem Banu Frousnoon, Nam Ngoc Pham, Zong‐Yen Wu, Ping-Hung Hsieh, Yasuo Yoshikuni

2025FEMS Yeast Research9 citationsDOIOpen Access PDF

Abstract

Yeasts play a vital role in both research and industrial biomanufacturing. Saccharomyces cerevisiae has been extensively utilized as a model system. However, its application is often constrained by limited tolerance to the diverse stress conditions encountered in bioprocesses. These challenges have driven increasing interest in nonconventional, multistress-tolerant yeasts as alternative biomanufacturing hosts. This review highlights Pichia kudriavzevii as a promising nonconventional yeast for industrial applications. Unlike S. cerevisiae, P. kudriavzevii exhibits exceptional tolerance to high temperatures, elevated concentrations of furanic and phenolic inhibitors, osmotic stress, salinity, and extreme pH. These traits make it an attractive candidate for industrial processes without requiring extensive genetic modifications to enhance stress resistance. As a result, P. kudriavzevii has emerged as a flagship species for advancing bioeconomy. Despite its industrial potential, the molecular mechanisms underlying P. kudriavzevii's superior stress tolerance remain poorly understood. This review compiles current knowledge on P. kudriavzevii and compares its stress tolerance mechanisms with those of S. cerevisiae, providing insights into its innate resilience. By expanding our understanding of nonconventional yeasts, this review aims to facilitate their broader adoption as robust microbial platforms for industrial biomanufacturing.

Topics & Concepts

BiomanufacturingBiologySaccharomyces cerevisiaeBiochemical engineeringYeastComputational biologyBiotechnologyGeneticsEngineeringFungal and yeast genetics researchFermentation and Sensory AnalysisMicrobial Metabolic Engineering and Bioproduction
Comparison of stress tolerance mechanisms between <i>Saccharomyces cerevisiae</i> and the multistress-tolerant <i>Pichia kudriavzevii</i> | Litcius