Structure and Hierarchy of Influenza Virus Models Revealed by Reaction Network Analysis

Overview

Journal Viruses

Publisher MDPI

Specialty Microbiology

Date 2019 May 19

PMID 31100972

Citations 6

Authors

Stephan Peter

Martin Holzer

Kevin Lamkiewicz

Pietro Speroni di Fenizio

Hassan Al Hwaeer

Manja Marz

Stefan Schuster

Peter Dittrich

Bashar Ibrahim

Affiliations

Soon will be listed here.

Abstract

Influenza A virus is recognized today as one of the most challenging viruses that threatens both human and animal health worldwide. Understanding the control mechanisms of influenza infection and dynamics is crucial and could result in effective future treatment strategies. Many kinetic models based on differential equations have been developed in recent decades to capture viral dynamics within a host. These models differ in their complexity in terms of number of species elements and number of reactions. Here, we present a new approach to understanding the overall structure of twelve influenza A virus infection models and their relationship to each other. To this end, we apply chemical organization theory to obtain a hierarchical decomposition of the models into chemical organizations. The decomposition is based on the model structure (reaction rules) but is independent of kinetic details such as rate constants. We found different types of model structures ranging from two to eight organizations. Furthermore, the model's organizations imply a partial order among models entailing a hierarchy of model, revealing a high model diversity with respect to their long-term behavior. Our methods and results can be helpful in model development and model integration, also beyond the influenza area.

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