Inhibition of Nipah Virus Infection In Vivo: Targeting an Early Stage of Paramyxovirus Fusion Activation during Viral Entry

In the paramyxovirus cell entry process, receptor binding triggers conformational changes in the fusion protein (F) leading to viral and cellular membrane fusion. Peptides derived from C-terminal heptad repeat (HRC) regions in F have been shown to inhibit fusion by preventing formation of the fusogenic six-helix bundle. We recently showed that the addition of a cholesterol group to HRC peptides active against Nipah virus targets these peptides to the membrane where fusion occurs, dramatically increasing their antiviral effect. In this work, we report that unlike the untagged HRC peptides, which bind to the postulated extended intermediate state bridging the viral and cell membranes, the cholesterol tagged HRC-derived peptides interact with F before the fusion peptide inserts into the target cell membrane, thus capturing an earlier stage in the F-activation process. Furthermore, we show that cholesterol tagging renders these peptides active in vivo: the cholesterol-tagged peptides cross the blood brain barrier, and effectively prevent and treat in an established animal model what would otherwise be fatal Nipah virus encephalitis. The in vivo efficacy of cholesterol-tagged peptides, and in particular their ability to penetrate the CNS, suggests that they are promising candidates for the prevention or therapy of infection by Nipah and other lethal paramyxoviruses.

Nipah (NiV) and Hendra (HeV) viruses are two lethal emerging zoonotic paramyxoviruses. In addition to acute infection, these viruses may lead to late-onset disease or relapse of encephalitis years after initial infection, as well as persistent or delayed neurological sequelae. We present a new strategy to prevent and treat NiV/HeV infection that may be broadly applicable for enveloped viral pathogens. Enveloped viruses must fuse their membrane with the target cell membrane in order to initiate infection, and blocking this step can prevent or treat infection, as clinically validated for HIV. For paramyxoviruses, however, peptides that bind the viral fusion protein have been shown to inhibit fusion in vitro, but not in vivo. The new strategy that we present here opens the door to clinically effective paramyxovirus fusion-inhibitory peptides. By targeting fusion-inhibitory peptides to the target membrane using a cholesterol tag, we capture an early stage in the viral fusion-activation process, thus drastically enhancing the efficacy of these peptides at inhibiting viral entry. Importantly, this strategy prevents and treats lethal Nipah virus infection in vivo. Membrane targeting of antiviral peptides thus offers a new approach to development of highly effective peptide fusion antivirals against important human pathogens.