TET-Yeasate: An engineered yeast whole-cell lysate-based approach for high performance tetracycline degradation

Qian He, Zhuoyu Lin, Meilin Qin, Yu Huang, Zhaoxiang Lu, Mei Zheng, Chaoyue Cui, Cang Li, Xiaojing Zhang, Xiaoping Liao, Yahong Liu, Hao Ren*, Jian Sun*

*Corresponding author for this work

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Abstract

The widespread of tetracycline (TC) residues in anthropogenic and natural environments pose an immediate threat to public health. Herein, we established the TET-Yeasate, an approach based on whole-cell lysate of engineered yeast, to mitigate the TC contamination in environment. The TET-Yeasate is defined as the biological matrix of whole cell lysate from engineered yeast that containing TC-degradative components (Tet(X), NADPH, Mg2+) and protective macromolecules. The TET-Yeasate was able to efficiently eliminate TC residues in tap water (98.8%), lake water (77.6%), livestock sewage (87.3%) and pharmaceutical wastewater (35.3%) without necessity for exogenous addition of expensive cofactors. The TET-Yeasate was further developed into lyophilized form for ease of storage and delivery. The TET-Yeasate in lyophilized form efficiently removed up to 74.6% TC residue within 0.25 h. In addition, the lyophilization confers promising resilience to TET-Yeasate against adverse temperatures and pH by maintaining degradation efficacy of 85.69%−97.83%. The stability test demonstrated that the biomacromolecules in lysate served as natural protectants that exerted extensive protection on TET-Yeasate during the 14-day storage at various conditions. In addition, 5 potential degradation pathways were elaborated based on the intermediate products. Finally, the analysis indicated that TET-Yeasate enjoyed desirable bio- and eco-safety without introduction of hazardous intermediates and spread of resistance genes. To summary, the TET-Yeasate based on whole cell lysate of engineered yeast provides a cost-effective and safe alternative to efficiently remove TC residues in environment, highlighting the great potential of such whole-cell based methods in environmental decontamination.
Original languageEnglish
Article number108158
Number of pages12
JournalEnvironment International
Volume179
Early online date17 Aug 2023
DOIs
Publication statusPublished - Sept 2023

Keywords

  • Tetracycline degradation
  • Engineered yeast
  • Whole cell lyasate
  • Lyophilization
  • Environmental decontamination

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