Abstract
Laboratory models have been invaluable for the field of microbiology for over 100 years and have provided key insights into core aspects of bacterial physiology such as regulation and metabolism. However, it is important to identify the extent to which these models recapitulate bacterial physiology within a human infection environment. Here, we performed transcriptomics (RNA-seq), focusing on the physiology of the prominent pathogen Staphylococcus aureusin situ in human cystic fibrosis (CF) infection. Through principal-component and hierarchal clustering analyses, we found remarkable conservation in S. aureus gene expression in the CF lung despite differences in the patient clinic, clinical status, age, and therapeutic regimen. We used a machine learning approach to identify an S. aureus transcriptomic signature of 32 genes that can reliably distinguish between S. aureus transcriptomes in the CF lung and in vitro The majority of these genes were involved in virulence and metabolism and were used to improve a common CF infection model. Collectively, these results advance our knowledge of S. aureus physiology during human CF lung infection and demonstrate how in vitro models can be improved to better capture bacterial physiology in infection.IMPORTANCE Although bacteria have been studied in infection for over 100 years, the majority of these studies have utilized laboratory and animal models that often have unknown relevance to the human infections they are meant to represent. A primary challenge has been to assess bacterial physiology in the human host. To address this challenge, we performed transcriptomics of S. aureus during human cystic fibrosis (CF) lung infection. Using a machine learning framework, we defined a "human CF lung transcriptome signature" that primarily included genes involved in metabolism and virulence. In addition, we were able to apply our findings to improve an in vitro model of CF infection. Understanding bacterial gene expression within human infection is a critical step toward the development of improved laboratory models and new therapeutics.
Highlights
Laboratory models have been invaluable for the field of microbiology for over 100 years and have provided key insights into core aspects of bacterial physiology such as regulation and metabolism
Building on a machine learning approach that was previously developed to study Pseudomonas aeruginosa human infections [24], we identified a transcriptomic signature of S. aureus during human cystic fibrosis (CF) lung infection
CF sputum samples were collected from the Emory Cystic Fibrosis Center (n ϭ 9) or from Denmark (n ϭ 1) from adult patients who were classified as clinically stable (Table 1)
Summary
Laboratory models have been invaluable for the field of microbiology for over 100 years and have provided key insights into core aspects of bacterial physiology such as regulation and metabolism. We used a machine learning approach to identify an S. aureus transcriptomic signature of 32 genes that can reliably distinguish between S. aureus transcriptomes in the CF lung and in vitro The majority of these genes were involved in virulence and metabolism and were used to improve a common CF infection model. Studies of S. aureus have centered on understanding mechanisms of virulence, regulation, and physiology and have typically been performed in liquid culture in a test tube or in animal infection models These studies have collectively uncovered complex regulatory networks that integrate quorum sensing, two-component systems, and sensing of both internal (e.g., metabolite levels) and external (e.g., host substrates) cues [14,15,16,17,18,19,20,21]. Advances in -omics techniques allow for global assessments of gene transcription, protein levels, and metabolite production by bacteria in their native environments [23,24,25,26,27]
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