AI Article Synopsis
- Many viruses utilize endosomal pathways to infiltrate cells, with endosomal acidification triggering the release of virus cores into the cytoplasm.
- Researchers synthesized four new derivatives of the vacuolar ATPase inhibitor diphyllin to improve its effectiveness against viral entry while minimizing toxicity.
- Some of these new compounds demonstrated significantly increased potency and selectivity, successfully inhibiting Ebola virus entry and replication in primary macrophages without causing high levels of cytotoxicity.
Article Abstract
Many viruses use endosomal pathways to gain entry into cells and propagate infection. Sensing of endosomal acidification is a trigger for the release of many virus cores into the cell cytosol. Previous efforts with inhibitors of vacuolar ATPase have been shown to block endosomal acidification and affect viral entry, albeit with limited potential for therapeutic selectivity. In this study, four novel series of derivatives of the vacuolar ATPase inhibitor diphyllin were synthesized to assess their potential for enhancing potency and anti-filoviral activity over cytotoxicity. Derivatives that suitably blocked cellular entry of Ebola pseudotyped virus were further evaluated as inhibitors of endosomal acidification and isolated human vacuolar ATPase activity. Several compounds with significant increases in potency over diphyllin in these assays also separated from cytotoxic doses in human cell models by >100-fold. Finally, three derivatives were shown to be inhibitors of replication-competent Ebola viral entry into primary macrophages with similar potencies and enhanced selectivity toward antiviral activity.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6387451 | PMC |
| http://dx.doi.org/10.1002/cmdc.201800587 | DOI Listing |
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