Evolutionary dynamics of Tn916 in Streptococcus oralis: Fitness cost and persistent metabolic shifts post-acquisition

IF 2.1 4区医学 Q2 DENTISTRY, ORAL SURGERY & MEDICINE

Archives of oral biology Pub Date : 2025-05-30 DOI:10.1016/j.archoralbio.2025.106317

Tracy Munthali Lunde , Supathep Tansirichaiya , Ying Xue , Mohammed Al-Haroni

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引用次数: 0

Abstract

Objectives

The acquisition and transfer of mobile genetic elements (MGEs) are major drivers of antibiotic resistance in bacterial populations. Despite the fitness cost associated with the acquisition of MGEs, the mechanisms underlying their persistence remain poorly understood. This study investigates the evolutionary dynamics of the integrative conjugative element (ICE) Tn916 in a naïve Streptococcus oralis host, focusing on growth rates and metabolic activity.

Methods

We tracked the evolutionary trajectory of Tn916 in S. oralis by monitoring changes in growth rates and maximum metabolic activities over 1000 generations. Comparative analyses were conducted between Tn916-free and Tn916-carrying populations to assess fitness cost and evolutionary adaptations.

Results

Following Tn916 integration, the S. oralis host exhibited a significant initial fitness cost, characterized by reduced growth rates and maximum metabolic activity. However, within 500 generations, the fitness cost was mitigated, and by 1000 generations, evolved Tn916- transconjugant populations outcompeted their unevolved counterparts. Despite the restoration of growth rates, a persistent reduction in maximum metabolic rate was observed, suggesting resource reallocation favoring growth and ICE maintenance.

Conclusion

The acquisition of Tn916 imposes initial fitness cost on S. oralis, but the cost is rapidly mitigated through evolution, leading to competitive advantages in the long term. However, the persistence of lower maximum metabolic rate indicates that Tn916 acquisition affects cellular functions beyond growth, underscoring the need to monitor metabolic activity to fully understand the impact of horizontal gene transfer, MGEs, and ICEs on bacterial populations.

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口腔链球菌Tn916的进化动力学：适应度成本和获取后的持续代谢变化

目的移动遗传元件（MGEs）的获取和转移是细菌群体产生抗生素耐药性的主要驱动因素。尽管适应度成本与mge的获得有关，但其持续存在的机制尚不清楚。本研究研究了整合共轭元件（ICE） Tn916在naïve口腔链球菌宿主中的进化动力学，重点研究了其生长速率和代谢活性。方法通过监测1000代口腔链球菌Tn916的生长速率和最大代谢活性的变化，追踪其进化轨迹。对不携带tn916的种群和携带tn916的种群进行了比较分析，以评估适应度成本和进化适应性。结果在整合Tn916后，口腔S. oralis宿主表现出显著的初始适应度成本，其特征是生长速率降低和代谢活性最大化。然而，在500代内，适应度成本得到了缓解，到1000代时，进化的Tn916-异共轭种群比未进化的种群更具竞争力。尽管恢复了生长速率，但观察到最大代谢速率持续下降，表明资源重新分配有利于生长和ICE维持。结论Tn916的获取会给口舌沙鼠带来初始适应度成本，但这种成本会通过进化得到快速缓解，从而形成长期的竞争优势。然而，持续较低的最大代谢率表明，Tn916获取影响细胞生长以外的功能，强调需要监测代谢活动，以充分了解水平基因转移、MGEs和ICEs对细菌种群的影响。

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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来源期刊

Archives of oral biology 医学-牙科与口腔外科

CiteScore

5.10

自引率

3.30%

发文量

177

审稿时长

26 days

期刊介绍： Archives of Oral Biology is an international journal which aims to publish papers of the highest scientific quality in the oral and craniofacial sciences. The journal is particularly interested in research which advances knowledge in the mechanisms of craniofacial development and disease, including: Cell and molecular biology Molecular genetics Immunology Pathogenesis Cellular microbiology Embryology Syndromology Forensic dentistry