Abstract
Limited structural information of drug targets, cellular toxicity possessed by lead compounds, and large amounts of potential leads are the major issues facing the design-oriented approach of discovering new leads. In an attempt to tackle these issues, we have developed a process of virtual screening based on the observation that conformational rearrangements of the dengue virus envelope protein are essential for the mediation of viral entry into host cells via membrane fusion. Screening was based solely on the structural information of the Dengue virus envelope protein and was focused on a target site that is presumably important for the conformational rearrangements necessary for viral entry. To circumvent the issue of lead compound toxicity, we performed screening based on molecular docking using structural databases of medical compounds. To enhance the identification of hits, we further categorized and selected candidates according to their novel structural characteristics. Finally, the selected candidates were subjected to a biological validation assay to assess inhibition of Dengue virus propagation in mammalian host cells using a plaque formation assay. Among the 10 compounds examined, rolitetracycline and doxycycline significantly inhibited plaque formation, demonstrating their inhibitory effect on dengue virus propagation. Both compounds were tetracycline derivatives with IC50s estimated to be 67.1 µM and 55.6 µM, respectively. Their docked conformations displayed common hydrophobic interactions with critical residues that affected membrane fusion during viral entry. These interactions will therefore position the tetracyclic ring moieties of both inhibitors to bind firmly to the target and, subsequently, disrupt conformational rearrangement and block viral entry. This process can be applied to other drug targets in which conformational rearrangement is critical to function.
Highlights
The Dengue virus (DV) belongs to the Flavivirus family and has become a major threat to public health globally, especially in tropical and subtropical areas, due to the increases in population density and environmental changes
For the eradication of infections caused by enveloped viruses, the identification of compounds that can block the function of viral envelope proteins to prevent viral entry has been a long-standing idea in the field
We have devised a scheme in which virtual screening (VS) focused on both the steric hindrance and atomic environment between the compounds and the targeted E protein to minimize the number of candidates
Summary
The Dengue virus (DV) belongs to the Flavivirus family and has become a major threat to public health globally, especially in tropical and subtropical areas, due to the increases in population density and environmental changes. Recent progress in the biology has brought with it many protein structures for virtual screening (VS) as drug targets [6,7,8,9]. Without a previously validated target site on the targeted protein as a reference point, the number of lead candidates obtained from this type of screening is very large. Cellular toxicity further complicates biological activity assays as well. The utilization of VS is somewhat hindered by the processes that follow, namely, the labor-intense, time-consuming verification process and the toxicity assays required for processing large amounts of lead candidates. To reduce the number of lead candidates, we further refined the VS output by structural clustering for the identification of novel structural characteristics. Compounds with novel structures were subjected to a biological assay to validate their activities. We sacrificed the diversity of leads in exchange for the efficiency of screening
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