Abstract
Respiratory viruses present major public health challenges, as evidenced by the 1918 Spanish Flu, the 1957 H2N2, 1968 H3N2, and 2009 H1N1 influenza pandemics, and the ongoing severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic. Severe RNA virus respiratory infections often correlate with high viral load and excessive inflammation. Understanding the dynamics of the innate immune response and its manifestations at the cell and tissue levels is vital to understanding the mechanisms of immunopathology and to developing strain-independent treatments. Here, we present a novel spatialized multicellular computational model of RNA virus infection and the type-I interferon-mediated antiviral response that it induces within lung epithelial cells. The model is built using the CompuCell3D multicellular simulation environment and is parameterized using data from influenza virus-infected cell cultures. Consistent with experimental observations, it exhibits either linear radial growth of viral plaques or arrested plaque growth depending on the local concentration of type I interferons. The model suggests that modifying the activity of signaling molecules in the JAK/STAT pathway or altering the ratio of the diffusion lengths of interferon and virus in the cell culture could lead to plaque growth arrest. The dependence of plaque growth arrest on diffusion lengths highlights the importance of developing validated spatial models of cytokine signaling and the need for in vitro measurement of these diffusion coefficients. Sensitivity analyses under conditions leading to continuous or arrested plaque growth found that plaque growth is more sensitive to variations of most parameters and more likely to have identifiable model parameters when conditions lead to plaque arrest. This result suggests that cytokine assay measurements may be most informative under conditions leading to arrested plaque growth. The model is easy to extend to include SARS-CoV-2-specific mechanisms or to use as a component in models linking epithelial cell signaling to systemic immune models.
Highlights
IntroductionTypical seasonal influenza virus strains are responsible for 290,000–650,000 annual deaths globally [1], and occasional, highly pathogenic pandemic strains, such as the 1918 Spanish Flu [2], and the 1957 H2N2 [3], 1968 H3N2 [4], and 2009 H1N1 [5] influenzas result in significantly higher mortality rates
Respiratory virus infections cause many deaths each year
In order to link molecular signaling at the site of infection to its impact on the overall interferon response and the occurrence of severe inflammation, we created a computational model of the early stages of infection that simulates lung cells infected with RNA viruses, such as those responsible for COVID19 and flu, to help explore how the disease forms viral plaques, an in vitro analog to lesion growth in the lung
Summary
Typical seasonal influenza virus strains are responsible for 290,000–650,000 annual deaths globally [1], and occasional, highly pathogenic pandemic strains, such as the 1918 Spanish Flu [2], and the 1957 H2N2 [3], 1968 H3N2 [4], and 2009 H1N1 [5] influenzas result in significantly higher mortality rates. As of June 29th, 2021, the SARS-CoV-2 virus, which causes COVID-19, has caused over 180 million recorded infections and 3.9 million deaths worldwide [6]. Both influenza and SARS-CoV-2 are RNA viruses, and studies of severe SARS-CoV-2 and influenza infections find that impaired interferon responses correlate with more severe outcomes [7,8,9]. Excessive inflammation exacerbates tissue damage and hinders clinical recovery [13,14]
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