Similarly, for individuals who have potential occupational exposu

Similarly, for individuals who have potential occupational exposure to Hendra and Nipah virus infection, such as pig ABT-199 chemical structure farmers and equine veterinarians, therapeutic agents and/or a vaccine to prevent infection would significantly reduce morbidity and mortality associated with Hendra and Nipah viruses. Hendra and Nipah virus attach to host cell-surface displayed ephrin-B2 or -B3 proteins and infect host cells by the coordinated activity of their attachment (G) and fusion (F) glycoproteins (reviewed in (Aguilar and Iorio, 2012 and Lee

and Ataman, 2011)). The G glycoprotein monomer consists of a stalk and globular head (Fig. 1) and the atomic structures of both the Nipah and Hendra virus G glycoprotein’s globular head domain have been determined alone and selleck compound in complex with ephrin proteins (reviewed in (Xu et al., 2012a)). The F glycoprotein mediates the membrane fusion process between the viral and host cell membranes by a Class I fusion mechanism that is initiated following the G glycoprotein engagement of ephrin receptor (Lee and Ataman, 2011). The susceptible host species and associated cellular tropism and pathology of Hendra and Nipah virus has in large part been explained by their use of the highly

conserved ephrin-B2 and -B3 proteins as entry receptors (reviewed in (Pernet et al., 2012 and Wong and Ong, 2011)). In addition and of importance to countermeasure development, the henipavirus G and F envelope glycoprotein spikes are major targets of virus-neutralizing antibodies and as discussed below, the development of potential vaccines have largely focused on these important structural components of the virion (reviewed in (Broder, Dehydratase 2010)). The development of medical countermeasures for use in humans is a time-consuming process, especially

for highly pathogenic BSL-4 agents like Hendra and Nipah virus where human efficacy trials are not feasible. Demonstrated efficacy in two animal models of disease is required to support possible licensure. In recent years monoclonal antibodies (mAbs) have attracted considerable attention as viable antiviral and antibacterial therapies, and the Food and Drug Administration (FDA) has approved both humanized and fully human monoclonal antibody (mAb) for use in preventing or treating infectious diseases in humans (Dolgin, 2013 and Zhu et al., 2013). The development of human monoclonal antibodies (humAbs) against Hendra and Nipah virus infection has been highly successful and as discussed below, a viable post-exposure mAb therapy is currently in development.

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