Highlights d 3,000 compounds screened in two cell types against SARS-CoV-2 d Entry pathways are distinct in hepatocyte Huh7.5 and respiratory Calu-3 cells d Only nine compounds that are active in Huh7.5 cells are active in Calu-3 cells d Cyclosporin and cyclophilin inhibitors block SARS-CoV-2 infection in diverse cells
There are an urgent need for antivirals to treat the newly emerged SARS-CoV-2. To identify new candidates we screened a repurposing library of ~3,000 drugs. Screening in Vero cells found few antivirals, while screening in human Huh7.5 cells validated 23 diverse antiviral drugs. Extending our studies to lung epithelial cells, we found that there are major differences in drug sensitivity and entry pathways used by SARS-CoV-2 in these cells. Entry in lung epithelial Calu-3 cells is pH-independent and requires TMPRSS2, while entry in Vero and Huh7.5 cells requires low pH and triggering by acid-dependent endosomal proteases. Moreover, we found 9 drugs are antiviral in lung cells, 7 of which have been tested in humans, and 3 are FDA approved including Cyclosporine which we found is targeting Cyclophilin rather than Calcineurin for its antiviral activity. These antivirals reveal essential host targets and have the potential for rapid clinical implementation.
Eumycetoma is a chronic subcutaneous neglected tropical disease that can be caused by more than 40 different fungal causative agents. The most common causative agents produce black grains and belong to the fungal orders Sordariales and Pleosporales. The current antifungal agents used to treat eumycetoma are itraconazole or terbinafine, however, their cure rates are low. To find novel drugs for eumycetoma, we screened 400 diverse drug-like molecules from the Pandemic Response Box against common eumycetoma causative agents as part of the Open Source Mycetoma initiative (MycetOS). 26 compounds were able to inhibit the growth of Madurella mycetomatis, Madurella pseudomycetomatis and Madurella tropicana, 26 compounds inhibited Falciformispora senegalensis and seven inhibited growth of Medicopsis romeroi in vitro. Four compounds were able to inhibit the growth of all five species of fungi tested. They are the benzimidazole carbamates fenbendazole and carbendazim, the 8-aminoquinolone derivative tafenoquine and MMV1578570. Minimal inhibitory concentrations were then determined for the compounds active against M. mycetomatis. Compounds showing potent activity in vitro were further tested in vivo. Fenbendazole, MMV1782387, ravuconazole and olorofim were able to significantly prolong Galleria mellonella larvae survival and are promising candidates to explore in mycetoma treatment and to also serve as scaffolds for medicinal chemistry optimisation in the search for novel antifungals to treat eumycetoma.
The current Covid-19
pandemic has underlined the need for a more
coordinated and forward-looking investment in the search for new medicines
targeting emerging health care threats. Repositioning currently approved
drugs is a popular approach to any new emerging disease, but it represents
a first wave of response. Behind this would be a second wave of more
specifically designed therapies based on activities against specific
molecular targets or in phenotypic assays. Following the successful
deployment and uptake of previous open access compound collections,
we assembled the Pandemic Response Box, a collection of 400 compounds
to facilitate drug discovery in emerging infectious disease. These
are based on public domain information on chemotypes currently in
discovery and early development which have been shown to have useful
activities and were prioritized by medicinal chemistry experts. They
are freely available to the community as a pharmacological test set
with the understanding that data will be shared rapidly in the public
domain.
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