Abstract
Many enveloped viruses enter cells through the endocytic network, from which they must subsequently escape through fusion of viral and endosomal membranes. This membrane fusion is mediated by virus-encoded spikes that respond to the dynamic endosomal environment, which triggers conformational changes in the spikes that initiate the fusion process. Several fusion triggers have been identified and include pH, membrane composition, and endosome-resident proteins, and these cues dictate when and where viral fusion occurs. We recently reported that infection with an enveloped bunyavirus requires elevated potassium ion concentrations [K(+)], controlled by cellular K(+) channels, that are encountered during viral transit through maturing endosomes. Here we reveal the molecular basis for the K(+) requirement of bunyaviruses through the first direct visualization of a member of the Nairoviridae family, namely Hazara virus (HAZV), using cryo-EM. Using cryo-electron tomography, we observed HAZV spike glycoproteins within infectious HAZV particles exposed to both high and low [K(+)], which showed that exposure to K(+) alone results in dramatic changes to the ultrastructural architecture of the virion surface. In low [K(+)], the spikes adopted a compact conformation arranged in locally ordered arrays, whereas, following exposure to high [K(+)], the spikes became extended, and spike-membrane interactions were observed. Viruses exposed to high [K(+)] also displayed enhanced infectivity, thus identifying K(+) as a newly defined trigger that helps promote viral infection. Finally, we confirmed that K(+) channel blockers are inhibitory to HAZV infection, highlighting the potential of K(+) channels as anti-bunyavirus targets.