Type IV pili facilitated natural competence in Fusobacterium nucleatum

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-08-01 DOI:10.1016/j.anaerobe.2023.102760

Blake E. Sanders, Ariana Umaña, Tam T.D. Nguyen, Kevin J. Williams, Christopher C. Yoo, Michael A. Casasanta, Bryce Wozniak, Daniel J. Slade

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Abstract

Objectives

Many bacterial species naturally take up DNA from their surroundings and recombine it into their chromosome through homologous gene transfer (HGT) to aid in survival and gain advantageous functions. Herein we present the first characterization of Type IV pili facilitated natural competence in Fusobacterium nucleatum, which is a Gram-negative, anaerobic bacterium that participates in a range of infections and diseases including periodontitis, preterm birth, and cancer.

Methods

Here we used bioinformatics on multiple Fusobacterium species, as well as molecular genetics to characterize natural competence in strain F. nucleatum subsp. nucleatum ATCC 23726.

Results

We bioinformatically identified components of the Type IV conjugal pilus machinery and show this is a conserved system within the Fusobacterium genus. We next validate Type IV pili in natural competence in F. nucleatum ATCC 23726 and show that gene deletions in key components of pilus deployment (pilQ) and cytoplasmic DNA import (comEC) abolish DNA uptake and chromosomal incorporation. We next show that natural competence may require native F. nucleatum DNA methylation to bypass restriction modification systems and allow subsequent genomic homologous recombination.

Conclusions

In summary, this proof of principle study provides the first characterization of natural competence in Fusobacterium nucleatum and highlights the potential to exploit this DNA import mechanism as a genetic tool to characterize virulence mechanisms of an opportunistic oral pathogen.

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IV型菌毛促进有核梭杆菌的自然能力。

目的：许多细菌物种自然地从周围环境中提取DNA，并通过同源基因转移（HGT）将其重组到染色体中，以帮助生存并获得有利的功能。在此，我们首次对核梭杆菌IV型菌毛促进的自然能力进行了表征，核梭杆菌是一种革兰氏阴性厌氧细菌，参与了一系列感染和疾病，包括牙周炎、早产和癌症。方法：我们利用多个梭杆菌属物种的生物信息学以及分子遗传学来表征具核梭杆菌亚种的自然能力。结果：我们生物信息学鉴定了IV型结合菌毛机制的成分，并表明这是梭杆菌属中的一个保守系统。接下来，我们在F.nucleanum ATCC 23726中验证了IV型菌毛的自然能力，并表明菌毛部署（pilQ）和细胞质DNA导入（comEC）的关键成分中的基因缺失消除了DNA摄取和染色体掺入。我们接下来表明，天然能力可能需要天然的有核F.DNA甲基化来绕过限制性修饰系统，并允许随后的基因组同源重组。结论：总之，这项原理验证研究首次对有核梭杆菌的自然能力进行了表征，并强调了利用这种DNA输入机制作为遗传工具来表征机会性口腔病原体毒力机制的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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