Abstract
Clinical diagnosis of acute infectious diseases during the early stages of infection is critical to administering the appropriate treatment to improve the disease outcome. We present a data driven analysis of the human cellular response to respiratory viruses including influenza, respiratory syncytia virus, and human rhinovirus, and compared this with the response to the bacterial endotoxin, Lipopolysaccharides (LPS). Using an anomaly detection framework we identified pathways that clearly distinguish between asymptomatic and symptomatic patients infected with the four different respiratory viruses and that accurately diagnosed patients exposed to a bacterial infection. Connectivity pathway analysis comparing the viral and bacterial diagnostic signatures identified host cellular pathways that were unique to patients exposed to LPS endotoxin indicating this type of analysis could be used to identify host biomarkers that can differentiate clinical etiologies of acute infection. We applied the Multivariate State Estimation Technique (MSET) on two human influenza (H1N1 and H3N2) gene expression data sets to define host networks perturbed in the asymptomatic phase of infection. Our analysis identified pathways in the respiratory virus diagnostic signature as prognostic biomarkers that triggered prior to clinical presentation of acute symptoms. These early warning pathways correctly predicted that almost half of the subjects would become symptomatic in less than forty hours post-infection and that three of the 18 subjects would become symptomatic after only 8 hours. These results provide a proof-of-concept for utility of anomaly detection algorithms to classify host pathway signatures that can identify presymptomatic signatures of acute diseases and differentiate between etiologies of infection. On a global scale, acute respiratory infections cause a significant proportion of human co-morbidities and account for 4.25 million deaths annually. The development of clinical diagnostic tools to distinguish between acute viral and bacterial respiratory infections is critical to improve patient care and limit the overuse of antibiotics in the medical community. The identification of prognostic respiratory virus biomarkers provides an early warning system that is capable of predicting which subjects will become symptomatic to expand our medical diagnostic capabilities and treatment options for acute infectious diseases. The host response to acute infection may be viewed as a deterministic signaling network responsible for maintaining the health of the host organism. We identify pathway signatures that reflect the very earliest perturbations in the host response to acute infection. These pathways provide a monitor the health state of the host using anomaly detection to quantify and predict health outcomes to pathogens.
Highlights
IntroductionHuman pathogens (bacteria, fungi, parasites, and viruses) induce a complex cascade of host responses that have evolved to detect the pathogen and minimize the disease severity [1]
Upon infection, human pathogens induce a complex cascade of host responses that have evolved to detect the pathogen and minimize the disease severity [1]
In order to test and validate the methodology, we explore Multivariate State Estimation Technique (MSET) for biological early warning using data generated by a mathematical model of the immune system’s response to infection as well as gene expression data sets arising in influenza and endotoxin experiments
Summary
Human pathogens (bacteria, fungi, parasites, and viruses) induce a complex cascade of host responses that have evolved to detect the pathogen and minimize the disease severity [1] This multicellular signaling network is triggered by pathogen-specific motifs and intracellular perturbations that activate/recruit host immune cells to infected sites and induce cell death of infected cells. The host’s ability to sense and control pathogen replication is primarily accomplished by the immune system Both the innate and adaptive immune response to a particular infectious agent is deliberate and dictated by a carefully orchestrated sequence of host signaling networks. By characterizing the pathogen-specific host signaling networks and the timing at which the pathways activate following infection, host-derived clinical assays could be developed to augment current medical diagnostic capabilities for acute infectious diseases. The challenge in such studies is to bridge the gap between single genes that serve a discriminative function from those that provide insight into the biological process of disease
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