Heidelberg [Germany]: Viruses such as influenza A and Ebola infiltrate human cells in a series of phases. Using electron scanning and computer simulations, research teams from Heidelberg University and Heidelberg University Hospital explored the last phases of viral penetration in an interdisciplinary approach. They were able to discover how the immune system fights off the virus in the instance of influenza A by employing a tiny protein.
They determined that in order for an Ebola virus infection to take hold, a certain protein structure must be deconstructed. These mechanisms rely heavily on so-called fusion pores, which allow the viral DNA to enter the host cell. If they are prevented from developing, the virus is also prevented from spreading. The Heidelberg researchers describe previously undiscovered pathways that could lead to novel approaches to infection prevention.
Many viruses that infect humans are covered with a lipid membrane that has glycoproteins that can dock with human cells. In viruses like influenza A, which enter through the respiratory tract, these are the spike proteins that mainly bind to epithelial cells in the nose and lungs. In contrast, the highly infectious Ebola virus spreads through direct contact with infected bodily fluids and can penetrate a broad spectrum of cell types. After invading human cells, these viruses must open a fusion pore between the virus membrane and the host membrane to release their genome into the host cell and propagate.
To fight off the virus, the human immune system attempts to block the formation of the fusion pore in a multi-stage process. Infected cells sense the presence of the foreign genome and send a signal, in the form of an interferon molecule, to as yet uninfected cells. This signal triggers the uninfected cells to produce a small cellular protein called interferon-induced transmembrane protein 3 (IFITM3). "This specialised protein can effectively prevent viruses such as influenza A, SARS-CoV-2, and Ebola from penetrating, but the underlying mechanisms were unknown," states virologist Dr Petr Chlanda, whose working group belongs to the BioQuant Center of Heidelberg University and the Center for Integrative Infectious Disease Research of Heidelberg University Hospital.
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