Identification of potential inhibitors targeting yellow fever virus helicase through ligand and structure-based computational studies.

Yellow fever is a flavivirus having plus-sensed RNA which encodes a single polyprotein. Host proteases cut this polyprotein into seven nonstructural proteins including a vital NS3 protein. The present study aims to identify the most effective inhibitor against the helicase (NS3) using different advanced ligand and structure-based computational studies. A set of 300 ligands was selected against helicase by chemical structural similarity model, which are similar to S-adenosyl-l-cysteine using infiniSee. This tool screens billions of compounds through a similarity search from in-built chemical spaces (CHEMriya, Galaxi, KnowledgeSpace and REALSpace). The pharmacophore was designed from ligands in the library that showed same features. According to the sequence of ligands, six compounds (29, 87, 99, 116, 148, and 208) were taken for pharmacophore designing against helicase protein. Subsequently, compounds from the library which showed the best pharmacophore shared-features were docked using FlexX functionality of SeeSAR and their optibrium properties were analyzed. Afterward, their ADME was improved by replacing the unfavorable fragments, which resulted in the generation of new compounds. The selected best compounds (301, 302, 303 and 304) were docked using SeeSAR and their pharmacokinetics and toxicological properties were evaluated using SwissADME. The optimal inhibitor for yellow fever helicase was 2-amino-N-(4-(dimethylamino)thiazol-2-yl)-4-methyloxazole-5-carboxamide (302), which exhibits promising potential for drug development.Communicated by Ramaswamy H. Sarma.

Duck IFIT5 differentially regulates Tembusu virus replication and inhibits virus-triggered innate immune response.

Mammalian interferon-induced protein with tetratricopeptide repeats family proteins (IFITs) play important roles in host innate immune response to viruses. Recently, studies have shown that IFIT from poultry also plays a crucial part in antiviral function. This study first reports the regulation of duck Tembusu virus (DTMUV) replication by IFIT5 and the effect of duck IFIT5 (duIFIT5) on the innate immune response after DTMUV infection. Firstly, duIFIT5 was obviously increased in duck embryo fibroblast cells (DEFs) infected with DTMUV. Compared to the negative control, we found that in the duIFIT5-overexpressing group, the DTMUV titer at 24 h post infection (hpi) was significantly reduced, but the viral titer was strikingly increased at 48 hpi. Moreover, overexpression of duIFIT5 could significantly inhibit IFN-ß transcription and IFN-ß promoter activation at indicated time points after DTMUV infection. Further, in DTMUV-infected or poly(I:C)-stimulated DEFs, overexpression of duIFIT5 also significantly inhibited the activation of NF-κB and IRF7 promoters, as well as the activation of downstream IFN induced the interferon-stimulated response element (ISRE) promoter. Meanwhile, the transcription level of antiviral protein Mx, but not OASL, was obviously decreased at various time points. The opposite results were obtained by knockdown of duIFIT5 in DTMUV-infected or poly(I:C)-stimulated DEFs. Compared to the negative control, knockdown of duIFIT5 promoted DTMUV titer and DTMUV envelope (E) protein expression at 24 hpi, but DTMUV titer and E protein expression was markedly decreased at 48 hpi. Additionally, the promoters of IFN-ß, NF-κB, IRF7 and ISRE were significantly activated in the duIFIT5 knockdown group. Collectively, duIFIT5 differentially regulates DTMUV replication and inhibits virus-triggered innate immune response.

Therapeutic effects of duck Tembusu virus capsid protein fused with staphylococcal nuclease protein to target Tembusu infection in vitro.

Tembusu virus (TMUV), a member of the genus flavivirus, primarily causes egg-drop syndrome in ducks and is associated with low disease mortality but high morbidity. The commercially available live vaccines for treating TMUV currently include the main WF100, HB, and FX2010-180P strains, and efficient treatment and/or preventative measures are still urgently needed. Capsid-targeted viral inactivation (CTVI) is a conceptually powerful new antiviral strategy that is based on two proteins from the capsid protein of a virus and a crucial effector molecule. The effector molecule can destroy the viral DNA/RNA or interfere with the proper folding of key viral proteins, while the capsid protein mainly plays a role in viral integration and assembly; the fusion proteins are incorporated into virions during packaging. This study aimed to explore the potential use of this strategy in duck TMUV. Our results revealed that these fusion proteins can be expressed in susceptible BHK21 cells without cytotoxicity and possess excellent Ca2+-dependent nuclease activity, and their expression is also detectable in DF-1 cells. Compared to those in the negative controls (BHK21 and BHK21/pcDNA3.1(+) cells), the numbers of viral RNA copies in TMUV-infected BHK21/Cap-SNase and BHK21/Cap-Linker-SNase cells were reduced by 48 h, and the effect of Cap-Linker-SNase was superior to that of Cap-SNase. As anticipated, these results suggest that these fusion proteins contribute to viral resistance to treatment. Thus, CTVI might be applicable for TMUV inhibition as a novel antiviral therapeutic candidate during viral infection.

Anticancer potential of quercetin: A comprehensive review.

Diet plays a key role to maintaining healthy life. Many natural products present in our diet, such as flavonoids, can prevent the progression of cancer. Quercetin, a distinctive bioactive flavonoid, is a dietary component that has attracted the attention of dietitians and medicinal chemists due to its numerous health-promoting effects. It is an outstanding antioxidant that has a well-documented role in reducing different human cancers. Quercetin exhibits direct proapoptotic effects on tumor cells and thus can inhibit the progress of numerous human cancers. The anticancer effect of quercetin has been documented in numerous in vitro and in vivo studies that involved several cell lines and animal models. On the other hand, the high toxic effect of quercetin against cancer cells is accompanied with little or no side effects or harm to normal cells. Accordingly, this review presents an overview of recent developments on the use of quercetin against different types of cancer along with mechanisms of action. In addition, the present review summarizes the literature pertaining to quercetin as an anticancer agent and provides an assessment of the potential utilization of this natural compound as a complimentary or alternative medicine for preventing and treating cancer.