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MeSH Disease

HGNC Genes

SARS-CoV-2 proteins

ProteinS (2)

ProteinN (2)

NSP5 (2)

ComplexRdRp (2)

ProteinM (1)


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    Discovery of Natural Phenol Catechin as a Multitargeted Agent Against SARS-CoV-2 For the Plausible Therapy of COVID-19 MESHD

    Authors: Chandra Bhushan Mishra; Preeti Pandey; Ravi Datta Sharma; Raj Kumar Mongre; Andrew M Lynn; Rajendra Prasad; Raok Jeon; Amresh Prakash

    doi:10.26434/chemrxiv.12752402.v1 Date: 2020-08-04 Source: ChemRxiv

    The global pandemic crisis, COVID-19 MESHD caused by severe acute respiratory syndrome coronavirus MESHD 2 (SARS-CoV-2) has claimed the lives of millions of people across the world. Development and testing of anti-SARS-CoV-2 drugs or vaccines, are not turned to be realistic in the timeframe needed to combat this pandemic. Thus, rigorous efforts are still ongoing for the drug repurposing as a clinical treatment strategy to control COVID-19 MESHD. Here we report a comprehensive computational approach to identify the multi-targeted drug molecules against the SARS-CoV-2 proteins, which are crucially involved in the viral-host interaction, replication of the virus inside the host, disease progression and transmission of coronavirus infection. Virtual screening of 72 FDA approved potential antiviral drugs against the target proteins: Spike (S PROTEIN) glycoprotein, human angiotensin-converting enzyme 2 ( hACE2 HGNC), 3-chymotrypsin- like cysteine protease PROTEIN ( 3CLpro PROTEIN), Cathepsin L HGNC, Nucleocapsid protein PROTEIN, RNA-dependent RNA polymerase PROTEIN ( RdRp PROTEIN) and nonstructural protein 6 ( NSP6 PROTEIN) resulted in the selection of seven drugs which preferentially binds to the target proteins. Further, the molecular interactions determined by MD simulation, free energy landscape and the binding free energy estimation, using MM-PBSA revealed that among 72 drug molecules, catechin (flavan-3-ol) can effectively bind to 3CLpro PROTEIN, Cathepsin L HGNC, RBD of S protein PROTEIN, NSP-6, and Nucleocapsid protein PROTEIN. It is more conveniently involved in key molecular interactions, showing binding free energy (ΔGbind) in the range of -5.09 kcal/mol ( Cathepsin L HGNC) to -26.09 kcal/mol ( NSP6 PROTEIN). At the binding pocket, catechin is majorly stabilized by the hydrophobic interactions, displays ΔEvdW values -7.59 to -37.39 kcal/mol. Thus, the structural insights of better binding affinity and favourable molecular interaction of catechin towards multiple target proteins, signifies that catechin can be potentially explored as a multitargeted agent in the rational design of effective therapies against COVID-19 MESHD.

    Temporal evolution and adaptation of SARS-COV 2 codon usage

    Authors: Maddalena Dilucca; Sergio Forcelloni; Andrea Giansanti; Alexandros Georgakilas; Athanasia Pavlopoulou

    doi:10.1101/2020.05.29.123976 Date: 2020-06-03 Source: bioRxiv

    The outbreak of severe acute respiratory syndrome-coronavirus-2 MESHD (SARS-CoV-2) has caused an unprecedented pandemic. Since the first sequenced whole-genome of SARS-CoV-2 on January 2020, the identification of its genetic variants has become crucial in tracking and evaluating their spread across the globe. In this study, we compared 15,259 SARS-CoV-2 genomes isolated from 60 countries since the outbreak of this novel coronavirus with the first sequenced genome in Wuhan to quantify the evolutionary divergence of SARS-CoV-2. Thus, we compared the codon usage patterns, every two weeks, of 13 of SARS-CoV-2 genes encoding for the membrane protein (M PROTEIN), envelope (E), spike surface glycoprotein (S PROTEIN), nucleoprotein (N PROTEIN), non-structural 3C-like proteinase ( 3CLpro PROTEIN), ssRNA-binding protein ( RBP HGNC), 2-O-ribose methyltransferase (OMT), endoRNase (RNase), helicase HGNC, RNA-dependent RNA polymerase PROTEIN ( RdRp PROTEIN), Nsp7, Nsp8, and exonuclease ExoN. As a general rule, we find that SARS-CoV-2 genome tends to diverge over time by accumulating mutations on its genome and, specifically, on the coding sequences for proteins N PROTEIN and S. Interestingly, different patterns of codon usage were observed among these genes. Genes S, Nsp7, NSp8, tend to use a norrower set of synonymous codons that are better optimized to the human host. Conversely, genes E PROTEIN and M consistently use a broader set of synonymous codons, which does not vary with respect to the reference genome. We identified key SARS-CoV-2 genes (S, N, ExoN, RNase, RdRp PROTEIN, Nsp7 and Nsp8) suggested to be causally implicated in the virus adaptation to the human host.

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MeSH Disease
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