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Polyhydroxyalkanoates production by yeasts - Still possible?

酵母によるポリヒドロキシアルカン酸の生産 - まだ可能か? (AI 翻訳)

Justyna Możejko-Ciesielska

Biotechnology Advances📚 査読済 / ジャーナル2026-08-31#その他Origin: Global
DOI: 10.1016/j.biotechadv.2026.108903
原典: https://doi.org/10.1016/j.biotechadv.2026.108903

🤖 gxceed AI 要約

日本語

本レビューは、酵母を用いた生分解性ポリマーであるポリヒドロキシアルカン酸(PHA)生産の現状と課題をまとめたものである。酵母は代謝の多様性や多様な基質利用能といった利点を持つが、現状では細菌システムと比較して生産性が低く、実用化には至っていない。遺伝子工学や人工知能技術の進展が将来的な課題克服の鍵となる可能性が議論されている。

English

This review summarizes the current state and challenges of polyhydroxyalkanoates (PHA) production using yeasts. Yeasts offer advantages such as metabolic versatility and diverse substrate utilization, but current productivity remains lower than bacterial systems. Advances in genetic engineering and artificial intelligence are discussed as potential future solutions.

Unofficial AI-generated summary based on the public title and abstract. Not an official translation.

📝 gxceed 編集解説 — Why this matters

日本のGX文脈において

日本ではバイオプラスチックの普及が進んでおり、PHAは生分解性プラスチックとして注目されている。本レビューは酵母によるPHA生産の可能性を探るもので、日本のバイオものづくり政策や循環経済に関連する。

In the global GX context

Bioplastics like PHA are gaining global attention as sustainable alternatives to conventional plastics. This review highlights the potential of yeast-based production, which could offer advantages in substrate flexibility and degradation, contributing to circular bioeconomy goals.

👥 読者別の含意

🔬研究者:Researchers in synthetic biology and biopolymer production will find a comprehensive overview of yeast PHA synthesis and future directions.

🏛政策担当者:Policymakers interested in bio-based materials and waste management may note the potential of yeast platforms for scalable bioplastic production.

📄 Abstract(原文)

Synthetic polymers have become ubiquitous in modern life due to their versatility, durability and low production costs, leading to a significant increase in global plastic consumption. However, their widespread use has led to serious environmental problems such as persistent pollution, biodiversity loss, health risks, and contributions to climate change. This highlights the urgent need for sustainable alternatives and improved waste management. Bioplastics currently account for only around 1 % of global plastics production, but their market share is growing. Among the biopolymer alternatives, polyhydroxyalkanoates (PHAs) are particularly attractive because they are microbially synthesized, bio-based, and biodegradable polyesters with a broad range of physical and thermoplastic properties, some of which are comparable to those of petroleum-derived polymers. To date, bacterial systems remain the dominant, most efficient, and industrially established platforms for PHA production, achieving substantially higher titres, yields, and productivities than yeast-based systems. Recent studies have nevertheless identified yeasts as promising alternative hosts for the production of PHA homo- and heteropolymers. Yeasts offer advantages such as metabolic versatility and the ability to utilise diverse substrates, and they may support both PHA synthesis and degradation. However, their current application remains at an early stage and is constrained by lower PHA production than in well-established bacterial hosts, as well as limited understanding and optimisation of the relevant metabolic and regulatory pathways. Advances in genetic engineering and artificial intelligence technologies may help overcome some of these barriers. These tools have not yet been widely applied directly to PHA-producing yeasts. They are discussed here primarily as promising emerging approaches for predictive strain design and bioprocess optimisation, as their direct application to yeast-based PHA production remains limited. This review summarises current knowledge on PHA synthesis in yeasts and discusses key limitations, technological bottlenecks, and future research directions needed for yeasts to become competitive PHA production platforms.

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