<p>RegIIIα is an antibacterial protein primarily operating in the digestive tract to defend against bacterial infection through direct bactericidal activity. A previous study proposed that RegIIIα forms hexameric pores on the membrane of Gram-positive bacteria, leading to cell lysis. These RegIIIα hexamers can further assemble into filaments, diminishing RegIIIα activity. However, the high-resolution structure of RegIIIα assembly remains elusive, impeding the comprehension of the molecular mechanisms underlying RegIIIα function. In this study, we determined the cryo-electron microscopy (cryo-EM) structure of RegIIIα filaments formed in vitro at a resolution of 2.2 Å. Our structure reveals a similar subunit arrangement but a distinct subunit orientation compared to the previously reported low-resolution model of RegIIIα filaments. Through structural analysis and biochemical assays, we identified two essential interfaces for RegIIIα assembly, offered a potential explanation for the necessity of lipids in RegIIIα assembly, and elucidated the inhibitory mechanism of the pro-segment of RegIIIα. Collectively, our study presents the first near-atomic structure of filaments formed by C-tyle lectin containing proteins, providing structural insights into RegIIIα assembly that are closely related to its physiological functions and regulations.</p>

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Structural basis for human RegⅢα filament formation

  • Jianting Han,
  • Qin Cao

摘要

RegIIIα is an antibacterial protein primarily operating in the digestive tract to defend against bacterial infection through direct bactericidal activity. A previous study proposed that RegIIIα forms hexameric pores on the membrane of Gram-positive bacteria, leading to cell lysis. These RegIIIα hexamers can further assemble into filaments, diminishing RegIIIα activity. However, the high-resolution structure of RegIIIα assembly remains elusive, impeding the comprehension of the molecular mechanisms underlying RegIIIα function. In this study, we determined the cryo-electron microscopy (cryo-EM) structure of RegIIIα filaments formed in vitro at a resolution of 2.2 Å. Our structure reveals a similar subunit arrangement but a distinct subunit orientation compared to the previously reported low-resolution model of RegIIIα filaments. Through structural analysis and biochemical assays, we identified two essential interfaces for RegIIIα assembly, offered a potential explanation for the necessity of lipids in RegIIIα assembly, and elucidated the inhibitory mechanism of the pro-segment of RegIIIα. Collectively, our study presents the first near-atomic structure of filaments formed by C-tyle lectin containing proteins, providing structural insights into RegIIIα assembly that are closely related to its physiological functions and regulations.