Exploring molecular moieties on carbonized polymer dots from flavonoid glycosides with activity against enterovirus A71
Journal
Carbon
Journal Volume
192
Pages
285-294
Date Issued
2022
Author(s)
Abstract
In recent years, numerous reports have revealed that hesperetin (Hsp) and its glycoside form, hesperidin (Hsd), exhibit significant antioxidant, anti-inflammatory, antibacterial, and antiviral activities. However, high concentrations of Hsp or Hsd are required to achieve in vivo therapeutic efficacy, since the accompanying toxicity has limited their use practical applications. To enhance bioactivity while reducing the potential associated toxicity, we synthesized carbonized polymer dots (CPDs) from hesperetin (Hsp) or hesperidin (Hsd) via mild pyrolysis and compared their antiviral activities with those of their raw precursors against enterovirus A71 (EV-A71). Our results showed that while Hsp and Hsd exhibited limited antiviral activity to suppress EV-A71-induced cytotoxicity in rhabdomyosarcoma cells, the CPDs possessed excellent antiviral activity with median effective concentration values of 44.2 and 17.7 μg mL??, respectively, demonstrating improved antiviral effects compared to Hsp and Hsd (each >200 μg mL??). Hsd-CPDs showed superior inhibition of EV-A71 infection compared to Hsp-CPDs, as shown by the >8-fold higher selectivity index. Molecular docking further suggests that apocynin and guaiacol moieties on the surface of the Hsd-CPDs could bind to the hydrophobic pocket of viral protein 1 of EV-A71, thus inhibiting viral attachment. We also demonstrated that Hsd-CPDs exert multiple mechanisms, including blocking viral entry and suppressing oxidative stress that triggered viral replication and translation. More importantly, Hsd-CPDs substantially alleviate the clinical symptoms and reduce death rates associated with EV-A71 infection in neonatal mice. Our results reveal the superior therapeutic effects of Hsd-CPDs against EV-A71 could be a potential antiviral agent worthy of future clinical investigation. © 2022 Elsevier Ltd
Subjects
Antiviral agents; Carbonized nanomaterials; Molecular moieties; Phytochemicals; Viral infections
Other Subjects
Antiviral agents; Mammals; Sugars; Toxicity; Anti-bacterial activity; Anti-inflammatory activity; Antiviral activities; Carbonized nanomaterial; Flavonoid glycosides; Glycoside forms; Molecular moieties; Phytochemical; Polymer dots; Viral infections; Flavonoids
Type
journal article