A MiRNA Host Response Signature Accurately Discriminates Acute Respiratory Infection Etiologies

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2019 Jan 9

PMID 30619110

Citations 12

Authors

Gregory D Poore

Emily R Ko

Ashlee Valente

Ricardo Henao

Kelsey Sumner

Christopher Hong

Thomas W Burke

Marshall Nichols

Micah T McClain

Erich S Huang

Geoffrey S Ginsburg

Christopher W Woods

Ephraim L Tsalik

Affiliations

Soon will be listed here.

Abstract

Acute respiratory infections (ARIs) are the leading indication for antibacterial prescriptions despite a viral etiology in the majority of cases. The lack of available diagnostics to discriminate viral and bacterial etiologies contributes to this discordance. Recent efforts have focused on the host response as a source for novel diagnostic targets although none have explored the ability of host-derived microRNAs (miRNA) to discriminate between these etiologies. In this study, we compared host-derived miRNAs and mRNAs from human H3N2 influenza challenge subjects to those from patients with pneumonia. Sparse logistic regression models were used to generate miRNA signatures diagnostic of ARI etiologies. Generalized linear modeling of mRNAs to identify differentially expressed (DE) genes allowed analysis of potential miRNA:mRNA relationships. High likelihood miRNA:mRNA interactions were examined using binding target prediction and negative correlation to further explore potential changes in pathway regulation in response to infection. The resultant miRNA signatures were highly accurate in discriminating ARI etiologies. Mean accuracy was 100% [88.8-100; 95% Confidence Interval (CI)] in discriminating the healthy state from pneumonia and 91.3% (72.0-98.9; 95% CI) in discriminating pneumonia from influenza infection. Subsequent differential mRNA gene expression analysis revealed alterations in regulatory networks consistent with known biology including immune cell activation and host response to viral infection. Negative correlation network analysis of miRNA:mRNA interactions revealed connections to pathways with known immunobiology such as interferon regulation and MAP kinase signaling. We have developed novel human host-response miRNA signatures for bacterial and viral ARI etiologies. miRNA host response signatures reveal accurate discrimination between pneumonia and influenza etiologies for ARI and integrated analyses of the host-pathogen interface are consistent with expected biology. These results highlight the differential miRNA host response to bacterial and viral etiologies of ARI, offering new opportunities to distinguish these entities.

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