下一代“魔弹”，源自微生物泛基因组的解决方案。

Next generation of "magic bullets", solutions from the microbial pangenome.

机构信息

GSK, 53100, Siena, Italy.

Fondazione Biotecnopolo di Siena, 53100, Siena, Italy.

出版信息

EMBO Mol Med. 2024 Oct;16(10):2271-2273. doi: 10.1038/s44321-024-00133-y. Epub 2024 Sep 6.

DOI:10.1038/s44321-024-00133-y

PMID:39242972

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11473682/

Abstract

Identification of a toxic agent that—like a sniper—would be capable of targeting pathogenic bacteria and effectively discriminating between “good” and “evil” cells has long been the holy grail of drug discovery. The theory of magic bullet, first pioneered by Paul Ehrlich in the early 1900, has represented since then a “ in immunological research against infectious diseases. Salvarsan, the first arsenic-based drug against syphilis, was the first example showing that this concept was in fact a realistic goal. Later, a paradigm shift took place with pathogenic bacteria becoming the source of the magic bullets (i.e., the toxins), and tumorigenic cells the enemy to combat; thus paving the way to immunotoxins discovery and development. In this issue of , Gill et al, describe a new toxin platform for cancer therapy (Gill et al, 2024).

摘要

长期以来，人们一直渴望发现一种能够像狙击手一样靶向致病性细菌、并能有效区分“好”细胞和“坏”细胞的有毒物质，这是药物研发的圣杯。魔法子弹理论最早由 Paul Ehrlich 在 20 世纪初提出，自那时以来，它一直是“抗感染免疫研究中的圣杯”。砷剂撒尔佛散是第一种对抗梅毒的药物，它首次表明这一概念实际上是一个现实的目标。后来，随着病原菌成为魔法子弹（即毒素）的来源，以及肿瘤细胞成为对抗的目标，发生了范式转变，从而为免疫毒素的发现和发展铺平了道路。在本期中，Gill 等人描述了一种用于癌症治疗的新型毒素平台（Gill 等人，2024 年）。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3953/11473682/9112e0ed1fa3/44321_2024_133_Fig1_HTML.jpg

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下一代“魔弹”，源自微生物泛基因组的解决方案。

Next generation of "magic bullets", solutions from the microbial pangenome.

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