Abstract
Orthopoxviruses (OPXVs) are an increasing threat to human health due to the growing population of OPXV-naive individuals after the discontinuation of routine smallpox vaccination. Antiviral drugs that are effective as postexposure treatments against variola virus (the causative agent of smallpox) or other OPXVs are critical in the event of an OPXV outbreak or exposure. The only US Food and Drug Administration-approved drug to treat smallpox, Tecovirimat (ST-246), exerts its antiviral effect by inhibiting extracellular virus (EV) formation, thereby preventing cell–cell and long-distance spread. We and others have previously demonstrated that host Golgi-associated retrograde proteins play an important role in monkeypox virus (MPXV) and vaccinia virus (VACV) EV formation. Inhibition of the retrograde pathway by small molecules such as Retro-2 has been shown to decrease VACV infection in vitro and to a lesser extent in vivo. To identify more potent inhibitors of the retrograde pathway, we screened a large panel of compounds containing a benzodiazepine scaffold like that of Retro-1, against VACV infection. We found that a subset of these compounds displayed better anti-VACV activity, causing a reduction in EV particle formation and viral spread compared to Retro-1. PA104 emerged as the most potent analog, inhibiting 90% viral spread at 1.3 μM with a high selectivity index. In addition, PA104 strongly inhibited two distinct ST-246-resistant viruses, demonstrating its potential benefit for use in combination therapy with ST-246. These data and further characterizations of the specific protein targets and in vivo efficacy of PA104 may have important implications for the design of effective antivirals against OPXV.
Highlights
The Orthopoxvirus (OPXV) genus contains several human pathogens of public health concern, including variola virus, monkeypox virus (MPXV), cowpox virus, and vaccinia virus (VACV, the virus that formulates the smallpox vaccine) (Fenner and Nakano, 1988)
These efforts resulted in the discovery of three compounds, PA24, PA63, and PA104, with impressive antiviral activity against VACV, the most potent and promising of which is PA104
The structural differences between these analogs and their parent Retro-1 have been highlighted in Figure 6, and nuclear magnetic resonance (NMR) and mass spectrometry (MS) data are provided in Supplementary Data Sheets S1, S2
Summary
The Orthopoxvirus (OPXV) genus contains several human pathogens of public health concern, including variola virus (the causative agent of smallpox), monkeypox virus (MPXV), cowpox virus, and vaccinia virus (VACV, the virus that formulates the smallpox vaccine) (Fenner and Nakano, 1988). OPXVs are large double-stranded DNA viruses that have a complex life cycle, replicate in the cytoplasm of infected cells, and generate two distinct virion forms: mature virus (MV) and extracellular virus (EV), differentiated based on the number of membranes surrounding the central DNA core (Condit et al, 2006). A proportion of MVs undergo double-membrane wrapping to generate wrapped virus (WV), which can stay attached to the infected cell (cellassociated virus) or exit the cell (EV) (Smith et al, 2002; Moss, 2006). EV particles constitute only 1–10% of MVs, they are essential for cell-to-cell and long-distance viral spread and play an important role in OPXV pathogenesis (Payne, 1980; Blasco and Moss, 1992; Engelstad and Smith, 1993). VACV mutants that fail to generate EVs produce small plaques in vitro and are attenuated in vivo, even in severely immunodeficient animal models (Blasco and Moss, 1991; Engelstad and Smith, 1993; Wolffe et al, 1993; Grosenbach et al, 2010)
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