Article Synopsis
- Intratumoural bacteria, specifically a 3:97 ratio of Proteus mirabilis (A-gyo) and Rhodopseudomonas palustris (UN-gyo), show strong antitumour effects without needing immune cell help.
- In mouse models, this bacterial combination led to complete tumour remission and prolonged survival without causing toxicity or cytokine release syndrome.
- The bacteria work by inducing intratumoural thrombosis and vascular collapse, resulting in significant tumour necrosis and directly attacking the cancer cells, creating a promising, safe strategy for targeted cancer therapy.
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Article Abstract
Intratumoural bacteria represent a promising drug-free strategy in cancer therapy. Here we demonstrate that a tumour-resident bacterial consortium-Proteus mirabilis (A-gyo) and Rhodopseudomonas palustris (UN-gyo)-in a precise 3:97 ratio (A-gyo:UN-gyo), exhibits potent antitumour efficacy independent of immune cell infiltration. In both immunocompetent and immunocompromised mouse models, including human tumour xenografts, intravenous administration of the bacterial consortium led to complete tumour remission, prolonged survival, and no observable systemic toxicity or cytokine release syndrome. Genomic and phenotypic analyses revealed A-gyo's unique non-pathogenic profile and impaired motility, while UN-gyo modulated A-gyo's biogenic activity, enhanced safety and promoted cancer-specific transformation. Mechanistically, the bacterial consortium triggered selective intratumoural thrombosis and vascular collapse-supported by cytokine induction, fibrin deposition and platelet aggregation-culminating in widespread tumour necrosis. The consortium also proliferated within tumours, formed biofilms and exerted direct oncolytic effects. This natural bacterial synergy-achieved without genetic engineering-offers a self-regulating and controllable strategy for safe, tumour-targeted therapy.
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| http://dx.doi.org/10.1038/s41551-025-01459-9 | DOI Listing |
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