Bacterial interactions underpin worsening lung function in cystic fibrosis-associated infections.

IF 5.1 1区 生物学 Q1 MICROBIOLOGY mBio Pub Date : 2024-11-22 DOI:10.1128/mbio.01456-24
Damian W Rivett, Lauren R Hatfield, Helen Gavillet, Michelle Hardman, Christopher van der Gast
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引用次数: 0

Abstract

Chronic lung infections are the primary cause of morbidity and early mortality in cystic fibrosis (CF) and, as such, have been the subject of a great deal of research. Subsequently, they have become one of the key paradigms for polymicrobial infections. The literature, however, has traditionally focused on the presence of pathogens in isolation or univariate measures like number of species to predict decline of lung function and ignores large swathes of data. Here, we suggest that looking at the interactions between species identified by 16S rRNA gene sequencing, rather than at species singularly, could elucidate hitherto unknown properties of these complicated infections. To confirm this, pooled samples from studies conducted by our laboratory, sequenced using the same pipeline, were used to assess microbiome-wide associations to lung function. We found pathogenic interactions between species were limited to the most abundant species, which were composed of canonical CF pathogens (including Pseudomonas, Staphylococcus, Stenotrophomonas, and Achromobacter) and commensals. This observation is crucial for better understanding of polymicrobial infections and treatment of these conditions while providing a simple framework for expanding this research into other disease states. The adoption of ecological principles into infection science can provide better understanding and options to those suffering from chronic conditions. The statistical ecology approach presented here enables clear hypotheses from observational data that can be ratified through subsequent manipulative experimental studies. Moreover, it can also be used to support the design and construction of clinically relevant in vitro models of polymicrobial infections.

Importance: Research studies have repeatedly demonstrated that chronic lung infection in cystic fibrosis is polymicrobial and consequently does not adhere to the single microbe-based Koch's postulates. Despite the plethora of evidence, the role of the constituent taxa present is largely unknown. Here we demonstrate how an ecological modeling perspective on lung infection microbiota can tease out potential interactions that alter progression of disease. Using techniques akin to genome-wide association studies, we show and validate 22 taxa, present in the chronic respiratory disease associated with cystic fibrosis, which have significant interactions that are negatively associated with patient lung function, the majority of which are "non-pathogenic" organisms. This work highlights the need to understand the interactive landscapes of the microbiomes to fully appreciate the complexity and treat chronic lung infections. Furthermore, this presents testable hypotheses for manipulative experiments in model systems to elucidate key mechanisms to driving disease progression.

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细菌相互作用是囊性纤维化相关感染导致肺功能恶化的基础。
慢性肺部感染是导致囊性纤维化(CF)患者发病和早期死亡的主要原因,因此一直是大量研究的主题。因此,慢性肺部感染已成为多微生物感染的主要范例之一。然而,文献传统上一直侧重于病原体的单独存在或物种数量等单变量指标来预测肺功能的下降,而忽略了大量数据。在这里,我们认为,研究 16S rRNA 基因测序确定的物种之间的相互作用,而不是单一地研究物种,可以阐明这些复杂感染迄今未知的特性。为了证实这一点,我们使用相同的管道对本实验室所做研究的样本进行了集中测序,以评估整个微生物组与肺功能的关联。我们发现物种间的致病性相互作用仅限于最丰富的物种,这些物种由典型的CF病原体(包括假单胞菌、葡萄球菌、臭单胞菌和 Achromobacter)和共生菌组成。这一观察结果对于更好地理解多微生物感染和治疗这些疾病至关重要,同时也为将这一研究扩展到其他疾病状态提供了一个简单的框架。在感染科学中采用生态学原理可以让慢性病患者更好地理解和选择治疗方案。本文介绍的统计生态学方法可以从观察数据中得出明确的假设,并通过随后的操作性实验研究加以验证。此外,它还可用于支持设计和构建与临床相关的多微生物感染体外模型:研究反复证明,囊性纤维化的慢性肺部感染是多微生物感染,因此并不符合基于单一微生物的科赫假说。尽管证据确凿,但其中的组成类群在很大程度上仍不为人知。在这里,我们展示了如何从生态建模的角度来看待肺部感染微生物群,从而找出改变疾病进展的潜在相互作用。利用类似于全基因组关联研究的技术,我们展示并验证了与囊性纤维化相关的慢性呼吸道疾病中存在的 22 个类群,这些类群具有显著的相互作用,与患者的肺功能呈负相关,其中大部分是 "非致病性 "生物。这项工作强调了了解微生物组交互景观的必要性,以充分认识其复杂性并治疗慢性肺部感染。此外,这还为模型系统中的操作实验提出了可检验的假设,以阐明推动疾病进展的关键机制。
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来源期刊
mBio
mBio MICROBIOLOGY-
CiteScore
10.50
自引率
3.10%
发文量
762
审稿时长
1 months
期刊介绍: mBio® is ASM''s first broad-scope, online-only, open access journal. mBio offers streamlined review and publication of the best research in microbiology and allied fields.
期刊最新文献
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