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揭示神经源性膀胱患者慢性定植的病原体特征

Unmasking Pathogen Traits for Chronic Colonization in Neurogenic Bladder Patients.

作者信息

Reasoner Seth A, Frainey Brendan T, Hale Owen F, Borden Alexandra, Graham M Kyle, Turner Elise, Brenes Lucas R, Soderstrom Carl B W, Green Hamilton, Schmitz Jonathan E, Laub Michael T, Kelly Maryellen S, Clayton Douglass B, Hadjifrangiskou Maria

机构信息

Division of Molecular Pathogenesis, Department of Pathology, Microbiology & Immunology, Vanderbilt University Medical Center, Nashville, TN.

Department of Urology, Vanderbilt University Medical Center, Nashville, TN.

出版信息

bioRxiv. 2025 Aug 14:2025.08.14.669717. doi: 10.1101/2025.08.14.669717.

DOI:10.1101/2025.08.14.669717
PMID:40832318
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12363967/
Abstract

Individuals with neurogenic bladder are particularly susceptible to both chronic bacterial colonization of the bladder and urinary tract infections (UTIs). Neurogenic bladder can arise from a variety of diseases such as diabetes, spinal cord injuries, and spina bifida. To study the ecological and evolutionary dynamics of the microbiome in neurogenic bladder, we developed a longitudinal cohort of 77 children and young adults with spina bifida from two medical centers. We used enhanced urine culture, 16S rRNA sequencing, and whole genome sequencing to characterize the microbial composition of urine and fecal samples. In addition to prospective sample collection, we retrieved prior bacterial isolates from enrolled patients from Vanderbilt's clinical microbial biobank, MicroVU. This allowed us to compare bacterial isolates from the same patients over a period of five years. Urine samples were characterized by high abundance of urinary pathogens, such as and . From longitudinal isolates from individual patients, we identified two common patterns of urinary tract colonization. We observed either the rapid cycling of strains and/or species, often following antibiotic treatment, or we observed the persistence of a single strain across timepoints. Neither persistence of a strain nor colonization with a new strain or species was associated with increased antibiotic resistance. Rather, in paired longitudinally collected strains from the same patients, mutations were identified in genes that code for cell envelope components associated with immune or phage evasion. Experimental testing revealed that O-antigen/LPS biosynthesis mutations confer protection from the immune system while altering susceptibility to phage predation, reflecting a fitness trade-off. We argue that this unparalleled cohort offers the opportunity to identify mechanisms of bacterial adaptation to the urinary tract that can be exploited in future therapeutic approaches.

摘要

神经源性膀胱患者特别容易发生膀胱慢性细菌定植和尿路感染(UTIs)。神经源性膀胱可由多种疾病引起,如糖尿病、脊髓损伤和脊柱裂。为了研究神经源性膀胱中微生物群的生态和进化动态,我们从两个医疗中心建立了一个由77名患有脊柱裂的儿童和年轻人组成的纵向队列。我们使用强化尿培养、16S rRNA测序和全基因组测序来表征尿液和粪便样本的微生物组成。除了前瞻性样本采集外,我们还从范德比尔特临床微生物生物库MicroVU中检索了已登记患者的先前细菌分离株。这使我们能够比较同一患者在五年内的细菌分离株。尿液样本的特征是尿路病原体丰度高,如 和 。从个体患者的纵向分离株中,我们确定了两种常见的尿路定植模式。我们观察到菌株和/或物种的快速循环,通常在抗生素治疗后出现,或者我们观察到单个菌株在不同时间点的持续存在。菌株的持续存在或新菌株或物种的定植均与抗生素耐药性增加无关。相反,在同一患者纵向收集的配对菌株中,在编码与免疫或噬菌体逃避相关的细胞包膜成分的基因中发现了突变。实验测试表明,O抗原/脂多糖生物合成突变在改变对噬菌体捕食易感性的同时赋予了对免疫系统的保护,反映了一种适应性权衡。我们认为,这个无与伦比的队列提供了机会来识别细菌适应尿路的机制,这些机制可在未来的治疗方法中加以利用。

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