病原体在泌尿道内的非浮游阶段对早期感染和抗药性进化的影响

Michael Raatz, Amanda de Azevedo-Lopes, Karolina Drabik, Arne Traulsen, Bartlomiej Waclaw
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引用次数: 0

摘要

治疗尿路感染和预防复发是一个紧迫的全球性健康问题。在泌尿系统感染中,致病细菌不仅存在于膀胱腔内,而且还会附着和侵入膀胱组织。浮游细菌、附着细菌和细胞内细菌面临着来自排尿、免疫反应和抗生素治疗等生理过程的不同选择压力。在这里,我们利用感染初始阶段的数学模型来揭示这些不同的选择压力对泌尿感染的生态和进化动态的影响。我们明确地模拟了膀胱腔内的浮游细菌、附着在膀胱壁上的细菌以及侵入膀胱上皮细胞的细菌。我们发现,非浮游细菌的存在大大增加了感染的风险,并影响了抗生素治疗过程中产生抗药性的进化轨迹。我们还发现,竞争性接种快速生长的非致病性菌株可以降低病原体负荷并提高抗生素的疗效,但前提是抗生素必须适度使用。我们的研究表明,要创建更逼真的泌尿感染模型,必须包括不同的分区,这可能有助于指导新的治疗策略。
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Pathogen non-planktonic phases within the urinary tract impact early infection and resistance evolution
Treatment of urinary tract infections and the prevention of their recurrence is a pressing global health problem. In a urinary infection, pathogenic bacteria not only reside in the bladder lumen but also attach to and invade the bladder tissue. Planktonic, attached, and intracellular bacteria face different selection pressures from physiological processes such as micturition, immune response, and antibiotic treatment. Here, we use a mathematical model of the initial phase of infection to unravel the effects of these different selective pressures on the ecological and evolutionary dynamics of urinary infections. We explicitly model planktonic bacteria in the bladder lumen, bacteria attached to the bladder wall, and bacteria that have invaded the epithelial cells of the bladder. We find that the presence of non-planktonic bacteria substantially increases the risk of infection establishment and affects evolutionary trajectories leading to resistance during antibiotic treatment. We also show that competitive inoculation with a fast-growing non-pathogenic strain can reduce the pathogen load and increase the efficacy of an antibiotic, but only if the antibiotic is used in moderation. Our study shows that including different compartments is essential to create more realistic models of urinary infections, which may help guide new treatment strategies.
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