Abstract
The Ebola virus (EBOV) has been recognised for nearly 40 years, with the most recent EBOV outbreak being in West Africa, where it created a humanitarian crisis. Mortalities reported up to 30 March 2016 totalled 11,307. However, up until now, EBOV drugs have been far from achieving regulatory (FDA) approval. It is therefore essential to identify parent compounds that have the potential to be developed into effective drugs. Studies on Ebola viral proteins have shown that some can elicit an immunological response in mice, and these are now considered essential components of a vaccine designed to protect against Ebola haemorrhagic fever. The current study focuses on chemoinformatic approaches to identify virtual hits against Ebola viral proteins (VP35 and VP40), including protein binding site prediction, drug-likeness, pharmacokinetic and pharmacodynamic properties, metabolic site prediction, and molecular docking. Retrospective validation was performed using a database of non-active compounds, and early enrichment of EBOV actives at different false positive rates was calculated. Homology modelling and subsequent superimposition of binding site residues on other strains of EBOV were carried out to check residual conformations, and hence to confirm the efficacy of potential compounds. As a mechanism for artefactual inhibition of proteins through non-specific compounds, virtual hits were assessed for their aggregator potential compared with previously reported aggregators. These systematic studies have indicated that a few compounds may be effective inhibitors of EBOV replication and therefore might have the potential to be developed as anti-EBOV drugs after subsequent testing and validation in experiments in vivo.
Highlights
Filoviridae, from the Ebola virus (EBOV) family, is a lipid-enveloped, negative-strand RNA virus that causes Ebola haemorrhagic disease, characterised by fever and an ensuing bleeding diathesis that has high mortality in both humans and non-human primates [1]
NMR mapping and high-resolution X-ray crystal structure of VP35 revealed that small compounds bind to the Ebola Interferon inhibitory domain, and to VP35 domains that are essential for the formation of the replication complex through molecular interactions with viral nucleoprotein
There were two basic patches in IID: the first basic patch (FBP) and central basic patch (CBP). The former is important for molecular interactions with the Ebola virus nucleoprotein and VP35 polymerase cofactor function, whilst the latter has its role in VP35 dsRNA binding and inhibition of IFN [38]
Summary
Filoviridae, from the EBOV family, is a lipid-enveloped, negative-strand RNA virus that causes Ebola haemorrhagic disease, characterised by fever and an ensuing bleeding diathesis that has high mortality in both humans and non-human primates [1]. EBOV has been acknowledged for nearly 40 years, the recent outbreak in West Africa has created an appalling situation in the region. The outbreak started in March 2014 in the Republic of Guinea, and has continued to spread throughout Sierra Leone and Liberia, where it is reported to be one of the largest outbreaks in history [2,3]. Mortality rates range from 53% to as high as 90%, with a total of 7178 cases reported until 1 October 2014 [4,5]. T2e0s16r,a1n7,g1e74f8rom 53% to as high as 90%, with a total of 7178 cases reported until 1 Oc2toobf e3r1 Jr.tMaloilt.yScria. t2e0s16r,a1n7,g1e74f8rom 53% to as high as 90%, with a total of 7178 cases reported until 1 Oc2toobf e3r1
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