Integrated host/microbe metagenomics enables accurate lower respiratory tract infection diagnosis in critically ill children

BACKGROUND Lower respiratory tract infection (LRTI) is a leading cause of death in children worldwide. LRTI diagnosis is challenging because noninfectious respiratory illnesses appear clinically similar and because existing microbiologic tests are often falsely negative or detect incidentally carried microbes, resulting in antimicrobial overuse and adverse outcomes. Lower airway metagenomics has the potential to detect host and microbial signatures of LRTI. Whether it can be applied at scale and in a pediatric population to enable improved diagnosis and treatment remains unclear. METHODS We used tracheal aspirate RNA-Seq to profile host gene expression and respiratory microbiota in 261 children with acute respiratory failure. We developed a gene expression classifier for LRTI by training on patients with an established diagnosis of LRTI (n = 117) or of noninfectious respiratory failure (n = 50). We then developed a classifier that integrates the host LRTI probability, abundance of respiratory viruses, and dominance in the lung microbiome of bacteria/fungi considered pathogenic by a rules-based algorithm. RESULTS The host classifier achieved a median AUC of 0.967 by cross-validation, driven by activation markers of T cells, alveolar macrophages, and the interferon response. The integrated classifier achieved a median AUC of 0.986 and increased the confidence of patient classifications. When applied to patients with an uncertain diagnosis (n = 94), the integrated classifier indicated LRTI in 52% of cases and nominated likely causal pathogens in 98% of those. CONCLUSION Lower airway metagenomics enables accurate LRTI diagnosis and pathogen identification in a heterogeneous cohort of critically ill children through integration of host, pathogen, and microbiome features. FUNDING Support for this study was provided by the Eunice Kennedy Shriver National Institute of Child Health and Human Development and the National Heart, Lung, and Blood Institute (UG1HD083171, 1R01HL124103, UG1HD049983, UG01HD049934, UG1HD083170, UG1HD050096, UG1HD63108, UG1HD083116, UG1HD083166, UG1HD049981, K23HL138461, and 5R01HL155418) as well as by the Chan Zuckerberg Biohub.

[1]  S. Sealfon,et al.  Benchmarking transcriptional host response signatures for infection diagnosis , 2022, Cell systems.

[2]  N. Neff,et al.  Upper airway gene expression shows a more robust adaptive immune response to SARS-CoV-2 in children , 2022, Nature Communications.

[3]  Juanjuan Xu,et al.  Metagenomic next-generation sequencing for accurate diagnosis and management of lower respiratory tract infections. , 2022, International journal of infectious diseases : IJID : official publication of the International Society for Infectious Diseases.

[4]  N. Neff,et al.  Lower respiratory tract infections in children requiring mechanical ventilation: a multicentre prospective surveillance study incorporating airway metagenomics , 2022, The Lancet. Microbe.

[5]  Jie Zhang,et al.  The Diagnostic Value of Metagenomic Next–Generation Sequencing in Lower Respiratory Tract Infection , 2021, Frontiers in Cellular and Infection Microbiology.

[6]  Ricardo Henao,et al.  Discriminating Bacterial and Viral Infection Using a Rapid Host Gene Expression Test* , 2021, Critical care medicine.

[7]  X. Tian,et al.  Lung Immune Tone via Gut-Lung Axis: Gut-derived LPS and Short-chain Fatty Acids' immunometabolic regulation of Lung IL-1β, FFAR2 and FFAR3 Expression. , 2021, American journal of physiology. Lung cellular and molecular physiology.

[8]  Xiaojuan Wang,et al.  Clinical Utility of In-house Metagenomic Next-generation Sequencing for the Diagnosis of Lower Respiratory Tract Infections and Analysis of the Host Immune Response. , 2020, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[9]  N. Neff,et al.  Upper airway gene expression reveals suppressed immune responses to SARS-CoV-2 compared with other respiratory viruses , 2020, Nature Communications.

[10]  S. Yooseph,et al.  Metatranscriptomics to characterize respiratory virome, microbiome, and host response directly from clinical samples , 2020, Cell reports methods.

[11]  J. Derisi,et al.  Temporal airway microbiome changes related to ventilator-associated pneumonia in children , 2020, European Respiratory Journal.

[12]  I. Amit,et al.  Single-cell landscape of bronchoalveolar immune cells in patients with COVID-19 , 2020, Nature Medicine.

[13]  Ryan King,et al.  IDseq—An open source cloud-based pipeline and analysis service for metagenomic pathogen detection and monitoring , 2020, bioRxiv.

[14]  M. Shi,et al.  High resolution metagenomic characterization of complex infectomes in paediatric acute respiratory infection , 2020, Scientific Reports.

[15]  J. E. Muñoz-Medina,et al.  Metagenomic sequencing with spiked primer enrichment for viral diagnostics and genomic surveillance , 2020, Nature Microbiology.

[16]  A. Agustí,et al.  Reduced airway levels of fatty-acid binding protein 4 in COPD: relationship with airway infection and disease severity , 2020, Respiratory Research.

[17]  Yate-Ching Yuan,et al.  Molecular profiling of innate immune response mechanisms in ventilator-associated pneumonia , 2020, bioRxiv.

[18]  Gennady Korotkevich,et al.  Fast gene set enrichment analysis , 2019, bioRxiv.

[19]  S. Madhi,et al.  Causes of severe pneumonia requiring hospital admission in children without HIV infection from Africa and Asia: the PERCH multi-country case-control study , 2019, The Lancet.

[20]  Gemma L. Kay,et al.  Nanopore metagenomics enables rapid clinical diagnosis of bacterial lower respiratory infection , 2019, Nature Biotechnology.

[21]  Doug Stryke,et al.  Clinical Metagenomic Sequencing for Diagnosis of Meningitis and Encephalitis. , 2019, The New England journal of medicine.

[22]  Katrina L Kalantar,et al.  Metagenomic comparison of tracheal aspirate and mini-bronchial alveolar lavage for assessment of respiratory microbiota. , 2019, American journal of physiology. Lung cellular and molecular physiology.

[23]  T. Blauwkamp,et al.  Analytical and clinical validation of a microbial cell-free DNA sequencing test for infectious disease , 2019, Nature Microbiology.

[24]  R. Lynfield,et al.  Changes in Prevalence of Health Care–Associated Infections in U.S. Hospitals , 2018, The New England journal of medicine.

[25]  N. Neff,et al.  FLASH: a next-generation CRISPR diagnostic for multiplexed detection of antimicrobial resistance sequences , 2018, bioRxiv.

[26]  T. Simon,et al.  Development and Validation of the Pediatric Medical Complexity Algorithm (PMCA) Version 3.0. , 2018, Academic pediatrics.

[27]  Katherine S. Pollard,et al.  Integrating host response and unbiased microbe detection for lower respiratory tract infection diagnosis in critically ill adults , 2018, Proceedings of the National Academy of Sciences.

[28]  Madeline Y Mayday,et al.  Pulmonary Metagenomic Sequencing Suggests Missed Infections in Immunocompromised Children , 2018, bioRxiv.

[29]  Ruth R. Montgomery,et al.  Aging impairs both primary and secondary RIG-I signaling for interferon induction in human monocytes , 2017, Science Signaling.

[30]  S. Cosgrove,et al.  Association of Adverse Events With Antibiotic Use in Hospitalized Patients , 2017, JAMA internal medicine.

[31]  Brian O'Donovan,et al.  Metagenomic Sequencing Detects Respiratory Pathogens in Hematopoietic Cellular Transplant Patients. , 2017, American journal of respiratory and critical care medicine.

[32]  Brett J. Kennedy,et al.  Viral Pathogen Detection by Metagenomics and Pan-Viral Group Polymerase Chain Reaction in Children With Pneumonia Lacking Identifiable Etiology , 2017, The Journal of infectious diseases.

[33]  Jamie Perin,et al.  Global, regional, and national causes of under-5 mortality in 2000–15: an updated systematic analysis with implications for the Sustainable Development Goals , 2016, The Lancet.

[34]  J. Jernigan,et al.  Estimating National Trends in Inpatient Antibiotic Use Among US Hospitals From 2006 to 2012. , 2016, JAMA internal medicine.

[35]  P. Khatri,et al.  Robust classification of bacterial and viral infections via integrated host gene expression diagnostics , 2016, Science Translational Medicine.

[36]  Lior Pachter,et al.  Near-optimal probabilistic RNA-seq quantification , 2016, Nature Biotechnology.

[37]  V. Pascual,et al.  Rhinovirus Detection in Symptomatic and Asymptomatic Children: Value of Host Transcriptome Analysis. , 2016, American journal of respiratory and critical care medicine.

[38]  Lawrence Carin,et al.  Host gene expression classifiers diagnose acute respiratory illness etiology , 2016, Science Translational Medicine.

[39]  M. Robinson,et al.  Differential analyses for RNA-seq: transcript-level estimates improve gene-level inferences. , 2015, F1000Research.

[40]  O. Ramilo,et al.  Superiority of Transcriptional Profiling Over Procalcitonin for Distinguishing Bacterial From Viral Lower Respiratory Tract Infections in Hospitalized Adults , 2015, The Journal of infectious diseases.

[41]  Matthew E. Ritchie,et al.  limma powers differential expression analyses for RNA-sequencing and microarray studies , 2015, Nucleic acids research.

[42]  W. Huber,et al.  Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2 , 2014, Genome Biology.

[43]  A. Zaas,et al.  The current epidemiology and clinical decisions surrounding acute respiratory infections. , 2014, Trends in molecular medicine.

[44]  J. Curtis,et al.  Analysis of Culture-Dependent versus Culture-Independent Techniques for Identification of Bacteria in Clinically Obtained Bronchoalveolar Lavage Fluid , 2014, Journal of Clinical Microbiology.

[45]  Jae-Hoon Chang,et al.  Inflammatory T cell responses rely on amino acid transporter ASCT2 facilitation of glutamine uptake and mTORC1 kinase activation. , 2014, Immunity.

[46]  Henning Hermjakob,et al.  The Reactome pathway knowledgebase , 2013, Nucleic Acids Res..

[47]  Xavier Robin,et al.  pROC: an open-source package for R and S+ to analyze and compare ROC curves , 2011, BMC Bioinformatics.

[48]  K. Frauwirth,et al.  Glutamine Uptake and Metabolism Are Coordinately Regulated by ERK/MAPK during T Lymphocyte Activation , 2010, The Journal of Immunology.

[49]  Trevor Hastie,et al.  Regularization Paths for Generalized Linear Models via Coordinate Descent. , 2010, Journal of statistical software.

[50]  L. Carin,et al.  Gene expression signatures diagnose influenza and other symptomatic respiratory viral infections in humans. , 2009, Cell host & microbe.

[51]  A. Krensky,et al.  Biology and clinical relevance of granulysin. , 2009, Tissue antigens.

[52]  Alex van Belkum,et al.  The role of nasal carriage in Staphylococcus aureus infections. , 2005, The Lancet. Infectious diseases.

[53]  Pablo Tamayo,et al.  Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[54]  Kurt Olsen,et al.  Epidemiology and clinical characteristics of community-acquired pneumonia in hospitalized children. , 2004, Pediatrics.

[55]  Christina Gloeckner,et al.  Modern Applied Statistics With S , 2003 .

[56]  T. Hansen [Children's hospital of Pittsburgh]. , 1995, Tidsskrift for den Norske laegeforening : tidsskrift for praktisk medicin, ny raekke.

[57]  D. Chung,et al.  Community-acquired pneumonia requiring hospitalization among U . S . adults , 2016 .

[58]  L. Finelli,et al.  Community-acquired pneumonia among U.S. children. , 2015, The New England journal of medicine.

[59]  C. Richart,et al.  Macrophages are novel sites of expression and regulation of retinol binding protein-4 (RBP4). , 2010, Physiological research.

[60]  Andy Liaw,et al.  Classification and Regression by randomForest , 2007 .

[61]  Joshua Lederberg,et al.  Children's Hospital of Philadelphia. , 1975, The Australasian nurses journal.