Ion channels play key roles in almost all facets of cellular physiology and have emerged as key host cell factors for a multitude of viral infections. A catalogue of ion channel-blocking drugs have been shown to possess antiviral activity, some of which are in widespread human usage for ion channel-related diseases, highlighting new potential for drug repurposing. The emergence of ion channel–virus interactions has also revealed the intriguing possibility that channelopathies may explain some commonly observed virus induced pathologies. This field is rapidly evolving and an up-to-date summary of new discoveries can inform future perspectives. We herein discuss the role of ion channels during viral lifecycles, describe the recently identified ion channel drugs that can inhibit viral infections, and highlight the potential contribution of ion channels to virus-mediated disease.
Article:Charlton, FW, Hover, S orcid.org/0000-0001-9190-5670, Fuller, J orcid.org/0000-0001-8801-149X et al. (4 more authors) (2019) Cellular cholesterol abundance regulates potassium accumulation within endosomes and is an important determinant in bunyavirus entry.
ABSTRACTThe Bunyavirales order of segmented negative-sense RNA viruses includes > 500 isolates that infect insects, animals, and plants and are often associated with severe and fatal disease in humans. To multiply their cholesterol requirement. Taken together, our findings suggest a model in which cholesterol abundance influences endosomal K + levels and consequently the efficiency of bunyavirus infection. The ability to inhibit bunyaviruses with existing cholesterol-lowering drugs may offer new options for future antiviral interventions for pathogenic bunyaviruses.
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The Bunyavirales order of segmented negative sense RNA viruses includes over 500 isolates that infect insects, animals, and plants, and are often associated with severe and fatal disease in humans. To multiply and cause disease, bunyaviruses must transport their genomes from outside the cell into the cytosol, achieved by transit through the endocytic network. We have previously shown that the model bunyaviruses Bunyamwera virus (BUNV) and Hazara virus (HAZV) exploit the changing potassium concentration ([K+]) of maturing endosomes to release their genomes at the appropriate endosomal location. K+ was identified as a biochemical cue to activate the viral fusion machinery, promoting fusion between viral and cellular membranes, consequently permitting genome release. In this study, we further define the biochemical prerequisites for BUNV and HAZV entry and their K+ dependence. We report four major findings: (1) BUNV and HAZV require cellular cholesterol during virus infection; (2) cholesterol is required during BUNV endosomal escape; (3) cholesterol depletion from host cells impairs their ability to accumulate K+ in maturing endosomes, revealing new insights into endosomal K+ homeostasis; (4) ‘priming’ BUNV virions with K+ prior to infection alleviates BUNV cholesterol requirement, revealing the mechanism of cholesterol dependence. Taken together, we provide a new model in which cholesterol abundance influences K+ endosomal homeostasis and consequently the efficiency of bunyavirus infection. The ability to inhibit bunyaviruses with existing cholesterol lowering drugs offers new options for future anti-bunyavirus interventions for pathogenic family members.
Following internalisation, viruses employ the changing environment of maturing endosomes as cues to promote endosomal escape, a process mediated by viral glycoproteins. Specifically, we previously showed that both high [K+] and low pH promote entry of Bunyamwera virus (BUNV), the prototypical bunyavirus. Here, we used sub-tomogram averaging combined with AlphaFold, to generate a pseudo-atomic model of the whole glycoprotein envelope of BUNV. This allowed us to unambiguously locate the Gc fusion domain and its chaperone Gn within the floor domain of the spike. We also confirmed that low pH and high [K+] alters the viral glycoproteins, resulting in an activated intermediate state functionally-distinct from the highly ordered ground state, and we localize these changes to the floor domain. Biochemical data suggests that in this intermediate state the viral fusion loops are partially exposed and selectively interact with host cell membranes. Taken together, we reveal new mechanistic understanding of the requirements for virus entry.
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