Structural basis for neutralization of hepatitis A virus informs a rational design of highly potent inhibitors.
Lei CaoPi LiuPan YangQiang GaoHong LiYao SunLing ZhuJianping LinDan SuZihe RaoXiangxi WangPublished in: PLoS biology (2019)
Hepatitis A virus (HAV), an enigmatic and ancient pathogen, is a major causative agent of acute viral hepatitis worldwide. Although there are effective vaccines, antivirals against HAV infection are still required, especially during fulminant hepatitis outbreaks. A more in-depth understanding of the antigenic characteristics of HAV and the mechanisms of neutralization could aid in the development of rationally designed antiviral drugs targeting HAV. In this paper, 4 new antibodies-F4, F6, F7, and F9-are reported that potently neutralize HAV at 50% neutralizing concentration values (neut50) ranging from 0.1 nM to 0.85 nM. High-resolution cryo-electron microscopy (cryo-EM) structures of HAV bound to F4, F6, F7, and F9, together with results of our previous studies on R10 fragment of antigen binding (Fab)-HAV complex, shed light on the locations and nature of the epitopes recognized by the 5 neutralizing monoclonal antibodies (NAbs). All the epitopes locate within the same patch and are highly conserved. The key structure-activity correlates based on the antigenic sites have been established. Based on the structural data of the single conserved antigenic site and key structure-activity correlates, one promising drug candidate named golvatinib was identified by in silico docking studies. Cell-based antiviral assays confirmed that golvatinib is capable of blocking HAV infection effectively with a 50% inhibitory concentration (IC50) of approximately 1 μM. These results suggest that the single conserved antigenic site from complete HAV capsid is a good antiviral target and that golvatinib could function as a lead compound for anti-HAV drug development.
Keyphrases
- high resolution
- electron microscopy
- transcription factor
- liver failure
- emergency department
- molecular dynamics simulations
- dengue virus
- molecular dynamics
- cancer therapy
- machine learning
- high throughput
- acute respiratory distress syndrome
- drug delivery
- intensive care unit
- anti inflammatory
- mesenchymal stem cells
- binding protein
- tandem mass spectrometry
- aedes aegypti
- respiratory failure
- protein protein