Search Results (7)

The dengue virus is globally widespread and has a high infection and fatality rate. Currently, no medication is available. So, this study aims to screen for promising inhibitors from Dodonaea viscosa by targeting NS5 methyltransferase (crucial in RNA capping) of the dengue virus. The compounds were screened from Dodonaea viscosa, and docking analysis was performed with the NS5 methyltransferase (PDB ID: 6KR2). Based on the docking investigation, the top five compounds were selected, having a score range of −7.164 to −5.837 Kcal/Mol, comparably higher than the control (Qunine; −3.050 Kcal/Mol), and examined. Among these selected compounds, Quercetin (PubChem ID; 5280343) revealed highly promising activity and was further analyzed for stability over 100 ns simulation. The ADME of the selected compound was examined and found to have favourable activity. Moreover, the compound can be used for therapeutic development to combat dengue infection. Full article

The rising incidence of dengue virus (DENV) infections in the tropical and sub-tropical regions of the world emphasizes the need to identify effective therapeutic drugs against the disease. Repurposing of drugs has emerged as a novel concept to combat pathogens. In this study, we employed a transcriptomics-based bioinformatics approach for drug identification against DENV. Gene expression omnibus datasets from patients with different grades of dengue disease severity and healthy controls were used to identify differentially expressed genes in dengue cases, which were then applied to the query tool of Connectivity Map to identify the inverse gene–disease–drug relationship. A total of sixteen identified drugs were investigated for their prophylactic, virucidal, and therapeutic effects against DENV. Focus-forming unit assay and quantitative RT-PCR were used to evaluate the antiviral activity. Results revealed that five compounds, viz., resveratrol, doxorubicin, lomibuvir, elvitegravir, and enalaprilat, have significant anti-DENV activity. Further, molecular docking studies showed that these drugs can interact with a variety of protein targets of DENV, including the glycoprotein, the NS5 RdRp, NS2B-NS3 protease, and NS5 methyltransferase The in vitro and in silico results, therefore, reveal that these drugs have the ability to decrease DENV-2 production, suggesting that these drugs or their derivatives could be attempted as therapeutic agents against DENV infections. Full article

Dengue virus (DENV) infection causes mild to severe illness in humans that can lead to fatality in severe cases. Currently, no specific drug is available for the treatment of DENV infection. Thus, the development of an anti-DENV drug is urgently required. Cordycepin (3′-deoxyadenosine), which is a major bioactive compound in Cordyceps (ascomycete) fungus that has been used for centuries in Chinese traditional medicine, was reported to exhibit antiviral activity. However, the anti-DENV activity of cordycepin is unknown. We hypothesized that cordycepin exerts anti-DENV activity and that, as an adenosine derivative, it inhibits DENV replication. To test this hypothesis, we investigated the anti-DENV activity of cordycepin in DENV-infected Vero cells. Cordycepin treatment significantly decreased DENV protein at a half-maximal effective concentration (EC50) of 26.94 μM. Moreover, DENV RNA was dramatically decreased in cordycepin-treated Vero cells, indicating its effectiveness in inhibiting viral RNA replication. Via in silico molecular docking, the binding of cordycepin to DENV non-structural protein 5 (NS5), which is an important enzyme for RNA synthesis, at both the methyltransferase (MTase) and RNA-dependent RNA polymerase (RdRp) domains, was predicted. The results of this study demonstrate that cordycepin is able to inhibit DENV replication, which portends its potential as an anti-dengue therapy. Full article

Dengue virus (DENV), a member of the family Flaviviridae, is a threat for global health as it infects more than 100 million people yearly. Approved antiviral therapies or vaccines for the treatment or prevention of DENV infections are not available. In the present study, natural compounds were screened for their antiviral activity against DENV by in vitro cell line-based assay. α-Mangostin, a xanthanoid, was observed to exert antiviral activity against DENV-2 under pre-, co- and post-treatment testing conditions. The antiviral activity was determined by foci forming unit (FFU) assay, quantitative RT-PCR and cell-based immunofluorescence assay (IFA). A complete inhibition of DENV-2 was observed at 8 µM under the co-treatment condition. The possible inhibitory mechanism of α-Mangostin was also determined by docking studies. The molecular docking experiments indicate that α-Mangostin can interact with multiple DENV protein targets such as the NS5 methyltransferase, NS2B-NS3 protease and the glycoprotein E. The in vitro and in silico findings suggest that α-Mangostin possesses the ability to suppress DENV-2 production at different stages of its replication cycle and might act as a prophylactic/therapeutic agent against DENV-2. Full article

Dengue infection is one of the most deleterious public health concerns for two-billion world population being at risk. Plasma leakage, hemorrhage, and shock in severe cases were caused by immunological derangement from secondary heterotypic infection. Flavanone, commonly found in medicinal plants, previously showed potential as anti-dengue inhibitors for its direct antiviral effects and suppressing the pro-inflammatory cytokine from dengue immunopathogenesis. Here, we chemically modified flavanones, pinocembrin and pinostrobin, by halogenation and characterized them as potential dengue 2 inhibitors and performed toxicity tests in human-derived cells and in vivo animal model. Dibromopinocembrin and dibromopinostrobin inhibited dengue serotype 2 at the EC₅₀s of 2.0640 ± 0.7537 and 5.8567 ± 0.5074 µM with at the CC₅₀s of 67.2082 ± 0.9731 and >100 µM, respectively. Both of the compounds also showed minimal toxicity against adult C57BL/6 mice assessed by ALT and Cr levels in day one, three, and eight post-intravenous administration. Computational studies suggested the potential target be likely the NS5 methyltransferase at SAM-binding pocket. Taken together, these two brominated flavanones are potential leads for further drug discovery investigation. Full article

Usutu virus (USUV) is a mosquito-borne arbovirus that has rapidly propagated in birds across several European countries over the last two decades, leading to substantial avian mortalities. USUV infection in humans has been associated with a growing number of cases of neurological disease in the last years, underlining the need for increased awareness and suitable treatments. Our group is working on the characterization of the NS5 protein of USUV. This protein is responsible for the replication activity of the viral genome and can be a suitable viral target to treat the infection. NS5 contains a RNA-dependent RNA polymerase (RdRpD) and a methyltransferase domains. Recombinant NS5 and RdRpD proteins expressed in bacteria were purified and biochemically characterized to determine the best conditions for their polymerase activities. Both proteins showed de novo and primer extension activities. Optimal RNA–polymerase reaction conditions included low NaCl (less than 20 mM), 2.5 mM MgCl₂ and 5 mM MnCl₂, 30 °C, and pH 7.25. Polymerase activity was cooperative for the polymerase domain (Hill coefficient = 5.8) but not for the complete NS5 (Hill coefficient = 1.2). To study their subcellular location, suitable sequences were cloned into a pcDNA3 vector and expressed in Huh7.5 and HEK293T cells. Both proteins were preferentially located in the cytoplasmic region, although a significant amount was found in the nucleus. Preliminary results showed that the concentration of sofosbuvir (SOFTP) necessary to achieve its incorporation by NS5 in 50% of the nascent RNA is higher than 100 µM, as already observed for dengue virus DENV. In this work, we describe the main features of the full-length USUV NS5, including the polymerase activity as well as the effect of protein–protein interactions and subcellular localization. Our results will be very useful for the study of this viral enzyme as a suitable target against the infection and the effect of antiviral drugs. Full article

Arthropod-borne flaviviruses such as tick-borne encephalitis virus (TBEV), West Nile virus (WNV), Zika virus (ZIKV), Dengue virus (DENV), and yellow fever virus (YFV) cause several serious life-threatening syndromes (encephalitis, miscarriages, paralysis, etc.). No effective antiviral therapy against these viruses has been approved yet. We selected, via in silico modeling, 12 U.S. Food and Drug Administration (FDA)-approved antiviral drugs (paritaprevir, dolutegravir, raltegravir, efavirenz, elvitegravir, tipranavir, saquinavir, dasabuvir, delavirdine, maraviroc, trifluridine, and tauroursodeoxycholic acid) for their interaction with ZIKV proteins (NS3 helicase and protease, non-structural protein 5 (NS5) RNA-dependent RNA polymerase, and methyltransferase). Only three of them were active against ZIKV, namely, dasabuvir (ABT-333), efavirenz, and tipranavir. These compounds inhibit virus replication of ZIKV (MR-766 and Paraiba_01) in Vero cells; therefore, we tested these compounds against other medically important flaviviruses WNV (13-104 and Eg101) and TBEV (Hypr). Dasabuvir was originally developed as an antiviral drug against hepatitis C virus (HCV); tipranavir and efavirenz are used for treating human immunodeficiency virus (HIV) infection. The antiviral effects of efavirenz, tipranavir, and dasabuvir were tested for ZIKV in HUH-7, astrocytes (HBCA), and UKF-NB-4 cells, where we also identified a significant inhibition effect of these compounds. For Vero cells, efavirenz inhibited all investigated viruses with EC₅₀ ranging from 9.70 to 29.26 µM; the tipranavir inhibition effect was from 16.19 (WNV 13-104) to 27.47 µM (TBEV), while the strongest and most robust antiviral effect was demonstrated in the case of dasabuvir (EC₅₀ values ranging from 9.09 (TBEV) to 10.85 µM (WNV 13-104)). These results warrant further research of these drugs, either individually or in combination, as possible pan-flavivirus inhibitors. Full article