核酸酶
质粒
机制(生物学)
效应器
四聚体
细胞生物学
噬菌体
免疫系统
化学
生物
血浆蛋白结合
HEK 293细胞
蛋白质结构
肽序列
先天免疫系统
核苷酸
生物物理学
结合位点
蛋白质结构域
序列(生物学)
领域(数学分析)
细胞
磷酸化
DNA
作者
Yan Li,David W. Adams,Hon Wing Liu,Steven J. Shaw,Emiko Uchikawa,Milena Jaskólska,Sandrine Stutzmann,Laurie Righi,Mark D. Szczelkun,Melanie Blokesch,Stephan Gruber
标识
DOI:10.1038/s41594-025-01677-4
摘要
Lamassu is a diverse family of defense systems that protect bacteria, including seventh-pandemic strains of Vibrio cholerae, against both plasmids and phage infection. During phage infection, Lamassu targets essential cellular processes, thereby halting phage propagation by terminating the infected host. The mechanisms by which Lamassu effectors are activated when needed and otherwise suppressed are unknown. Here we present structures of a Lamassu defense system from Salmonella enterica. We show that an oligomerization domain of the nuclease effector subunit, LmuA, is sequestered by two tightly folded SMC-like LmuB protomers and LmuC. Upon activation, liberated LmuA assembles into homotetramers, in which two of four nuclease domains are brought into proximity to create an active site capable of cleaving DNA. We propose that tetramer formation is likely a one-way switch that establishes a threshold to limit potential spontaneous activation and cell death. Our findings reveal a mechanism of cellular defense, involving liberation and oligomerization of immune effectors, and shed light on how Lamassu systems balance potent immune responses with self-preservation. Li et al. show that a Lamassu defense system protects bacteria from phage infection by activating a lethal tetrameric DNA-cutting enzyme. In the absence of phages, a protein clamp holds the enzyme as an inactive monomer, preventing self-damage.
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