Targeted tumor therapy with L-cyst(e)ine-addicted bacteria-nanodrug biohybrids

IF 27.7 1区生物学 Q1 CELL BIOLOGY

Cell metabolism Pub Date : 2025-04-10 DOI:10.1016/j.cmet.2025.03.012

Yu-Zhang Wang, Wei-Hai Chen, Zi-Yi Han, Shi-Man Zhang, Ping Ji, Cheng Zhang, Jun-Long Liang, Xian-Zheng Zhang

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Abstract

Bacteria-based metabolic therapy has been acknowledged as a promising strategy for tumor treatment. However, the insufficient efficiency of wild-type bacteria severely restricts their therapeutic efficacy. Here, we elaborately develop an ʟ-cyst(e)ine-addicted bacteria-nanodrug biohybrid for metabolic therapy through a dual-selection directed evolution strategy. Our evolved strain exhibits a 36-fold increase in ʟ-cystine uptake and a 23-fold improvement in total activity of cysteine desulfhydrases compared with the wild-type strain. By conjugating with DMXAA-loaded liposomes, the engineered bacteria-nanodrug biohybrid not only prevents the influx of nutrients into the tumor by blocking neovasculature but also achieves efficient and durable CySS catabolism locally. The unavailable of Cys species disrupts redox homeostasis and strikingly increases intracellular ROS level, achieving favorable therapeutic outcomes in multiple tumor models. Our study not only highlights the promise of directed evolution strategy in enhancing the stability and efficiency of bacteria-based living biocatalyst but also provides new opportunities for antitumor metabolic therapy.

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l -囊肿(e)嗜碱细菌-纳米药物生物杂合体靶向肿瘤治疗

以细菌为基础的代谢疗法已被认为是一种很有前途的肿瘤治疗策略。然而，野生型细菌的效率不足严重制约了其治疗效果。在这里，我们通过双选择定向进化策略精心开发了用于代谢治疗的 -囊肿(e)ine成瘾细菌-纳米药物生物杂交体。我们的进化菌株显示，与野生型菌株相比， -胱氨酸摄取增加了36倍，半胱氨酸脱硫酶的总活性提高了23倍。通过与负载dmxha的脂质体结合，工程细菌-纳米药物生物杂合体不仅通过阻断新生血管阻止营养物质流入肿瘤，而且还实现了高效持久的局部CySS分解代谢。Cys的缺失破坏了氧化还原稳态，显著增加了细胞内ROS水平，在多种肿瘤模型中获得了良好的治疗效果。我们的研究不仅突出了定向进化策略在提高细菌活性生物催化剂稳定性和效率方面的前景，而且为抗肿瘤代谢治疗提供了新的机会。

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来源期刊

Cell metabolism 生物-内分泌学与代谢

CiteScore

48.60

自引率

1.40%

发文量

173

审稿时长

2.5 months

期刊介绍： Cell Metabolism is a top research journal established in 2005 that focuses on publishing original and impactful papers in the field of metabolic research.It covers a wide range of topics including diabetes, obesity, cardiovascular biology, aging and stress responses, circadian biology, and many others. Cell Metabolism aims to contribute to the advancement of metabolic research by providing a platform for the publication and dissemination of high-quality research and thought-provoking articles.