The natural polyphenol proanthocyanidin A2 prevents the in vitro infection of Ebola virus and rabies virus by interfering with the early phases of the replication cycle

The Ebola virus (EBOV) and the Rabies virus (RABV) are deadly infectious agents impacting human and animal health. Current prevention and control strategies mainly rely on vaccines and antibodies, highlighting the urgent need for effective, low-cost antivirals suitable for therapeutic options. Plant-derived bioactive compounds offer a promising natural source for such candidate antivirals. As a contribution to this antiviral approach, we have characterized the anti-EBOV and anti-RABV activity of a Cranberry extract (CE) endowed with a very high content of bioactive A2-type proanthocyanidin (PAC-A2). The CE inhibited the in vitro infection of both pseudoviruses expressing EBOV-GP or RABV-G glycoproteins and authentic EBOV and RABV. Attachment and entry assays revealed that the extract targets early phases of infection preventing attachment and entry. Noteworthy, synthetic PAC-A2 reproduced the antiviral activity observed with the whole CE. Mechanistic studies then revealed that the CE interacted directly with the ectodomain of EBOV-GP or the RABV-G, suggesting interference with their functions. In support to this hypothesis, fluorescence spectroscopy analysis showed a reduction in intrinsic fluorescence of both EBOV-GP and RABV-G after incubation with synthetic PAC-A2, thus confirming a direct interaction of the viral glycoproteins with PAC-A2. In silico docking simulations further sustained in vitro results by predicting the binding of PAC-A2 into the binding pocket of EBOV-GP and to the trimeric architecture of RABV-G. Together, these results suggest this cranberry extract and bioactive PAC-A2 as potential candidates to be further develop as novel antiviral agents for the prevention of EBOV and RABV infections.