Computational model of hepatitis B virus DNA polymerase: Molecular dynamics and docking to understand resistant mutations

Daga, Pankaj; Duan, Jingliang; Doerksen, Robert J.

doi:10.1002/pro.359

Cited by 38 publications

(44 citation statements)

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“…Due to its importance as a drug target (all five currently approved chemotherapeutics for hepatitis B virus are nucleos [t]idic RT inhibitors [NRTIs] [31]), several models for the RT domain of the HBV P protein have been calculated by using HIV-1 RT as the template (5,16,17,50). The rationale is the presence in the RT domains of all P proteins of short motifs (boxes A to E plus box F [or box II] and box G [or box I] [ Fig.…”

mentioning

confidence: 99%

Extensive Mutagenesis of the Conserved Box E Motif in Duck Hepatitis B Virus P Protein Reveals Multiple Functions in Replication and a Common Structure with the Primer Grip in HIV-1 Reverse Transcriptase

Wang

Luo

Zhao

et al. 2012

J Virol

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c Hepadnaviruses, including the pathogenic hepatitis B virus (HBV), replicate their small DNA genomes through protein-primed reverse transcription, mediated by the terminal protein (TP) domain in their P proteins and an RNA stem-loop, ⑀, on the pregenomic RNA (pgRNA). No direct structural data are available for P proteins, but their reverse transcriptase (RT) domains contain motifs that are conserved in all RTs (box A to box G), implying a similar architecture; however, experimental support for this notion is limited. Exploiting assays available for duck HBV (DHBV) but not the HBV P protein, we assessed the functional consequences of numerous mutations in box E, which forms the DNA primer grip in human immunodeficiency virus type 1 (HIV-1) RT. This substructure coordinates primer 3=-end positioning and RT subdomain movements during the polymerization cycle and is a prime target for nonnucleosidic RT inhibitors (NNRTIs) of HIV-1 RT. Box E was indeed critical for DHBV replication, with the mutations affecting the folding, ⑀ RNA interactions, and polymerase activity of the P protein in a position-and amino acid side chain-dependent fashion similar to that of HIV-1 RT. Structural similarity to HIV-1 RT was underlined by molecular modeling and was confirmed by the replication activity of chimeric P proteins carrying box E, or even box C to box E, from HIV-1 RT. Hence, box E in the DHBV P protein and likely the HBV P protein forms a primer grip-like structure that may provide a new target for anti-HBV NNRTIs. Hepadnaviruses are small hepatotropic DNA viruses that infect humans and select mammals and birds. Hepatitis B virus (HBV), one of the most relevant viral pathogens of humans (20), is their prototypic member. All hepadnaviruses replicate their ϳ3.0-kb genomes by chaperone-assisted protein-primed reverse transcription (10), executed by their P proteins. These are unusual reverse transcriptases (RTs), which, beyond the common RNA-dependent and DNA-dependent DNA polymerase and RNase H (RH) domains, contain a unique terminal protein (TP) domain at their N termini (Fig. 1A). To initiate reverse transcription, the phenolic OH group of a specific Tyr residue in TP fills the role that conventionally is taken by the 3=-hydroxyl end of a nucleic acid primer (30).P proteins are translated from a greater-than-genome-length transcript, the pregenomic RNA (pgRNA), which also acts as mRNA for the viral core protein. The interaction of the P protein with an RNA stem-loop, ⑀, on the pgRNA is crucial for viral replication; it triggers the coencapsidation of pgRNA and the P protein into newly forming nucleocapsids and the synthesis of a short DNA oligonucleotide, which is templated by the bulge in ⑀ and, via its 5=-terminal nucleotide, becomes covalently attached to the Tyr residue in TP ("protein priming"). Upon transfer to a 3=-proximal acceptor site on pgRNA, the oligonucleotide is extended into fulllength minus-strand DNA, and the pgRNA template is concurrently degraded by the P protein's RH activity. Some 15 to 18 residues fro...

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confidence: 99%

Extensive Mutagenesis of the Conserved Box E Motif in Duck Hepatitis B Virus P Protein Reveals Multiple Functions in Replication and a Common Structure with the Primer Grip in HIV-1 Reverse Transcriptase

Wang

Luo

Zhao

et al. 2012

J Virol

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“…The five vanitaracin derivatives obtained from Talaromyces species [23] and three known inhibitors namely entecavir, telbivudine and tenofivir [15] were drawn using sketch molecule function in SYBYLX2.0. The energy minimization of the molecules was performed using Tripos force field and Gasteiger Huckel charge.…”

Section: Ligand Preparationmentioning

confidence: 99%

“…Although HBV infection can be largely prevented by use of effective vaccine, not everyone is vaccinated and there is no vaccine for the people who are already chronically infected. Therefore, there is continuous need for antiviral drugs to suppress viral replication or eliminate infection [15] and antiviral resistance is considered to be one of the most important factors associated with HBV treatment failure [16] and it determines the success of long-term therapy for chronic hepatitis B. Consequently, there is an urgent need to explore novel classes of drugs with different antiviral targets containing anti-HBV agents. Molecular docking plays an important role in drug designing by placing a ligand molecule into the binding site of the target molecule [17] and is demonstrated in the following studies [18][19][20] .…”

Section: Introductionmentioning

confidence: 99%

Molecular Docking Study of Novel Anti-Hepatitis B Virus Agents Isolated from Talaromyces Species

Babu¹

2016

Journal of the Chosun Natural Science

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Hepatitis B virus is the leading source of liver disorders and is a global health problem and needs advancements in its treatment against increasing problems. Recently five vanitaracin derivatives were isolated from the fungus Talaromyces species which have anti-Hepatitis B virus activity. Hence, in the present study, molecular docking was carried out with five vanitaracin derivatives isolated from Talaromyces species and three known inhibitors.The objective of this work is to study the interaction of newly isolated compounds and compare its interaction with known inhibitors. The docking results revealed that vanitaracin derivatives have good interactions and has better docking score with the Hepatitis B virus and suggest SER2, SER4 and ASP30 are important residues involved in interaction with the inhibitors. These result authenticates vanitaracin derivatives contributes to inhibitory activity of Hepatitis B virus to treat liver disorders.

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“…Homology modelling and flexibility of binding residue by normal mode analysis A homology model of HDP was obtained using previously described methods (Langley et al 2007;Daga et al 2010;Ismail et al 2010;Kim et al 2010). HIV-1 RT shares a sufficient structural and functional similarity with HDP and can serve as a template for modelling the tertiary structure of HDP (Daga et al 2010).…”

Section: Data Setmentioning

confidence: 99%

“…HIV-1 RT shares a sufficient structural and functional similarity with HDP and can serve as a template for modelling the tertiary structure of HDP (Daga et al 2010). The model for the native HDP was thus constructed with SWISS-MODEL (Schwede et al 2003) using the structure of the HIV-1 RT [Huang et al 1998; Protein Data Bank (PDB) code: 1RTD] as the template structure.…”

Section: Data Setmentioning

confidence: 99%

Analysis of hepatitis B virus drug-resistant mutation (M204V) using molecular dynamics simulation techniques

Muralidharan

Ramanathan

2014

Biologia

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Hepatitis B virus (HBV) is the most common cause of liver infection. This can be treated by targeting HBV DNA polymerase (HDP). Although many drugs are available for the treatment, lamivudine is widely used because of its good safety profiles. Lamivudine targets the reverse transcriptase activity of HDP and restricts the viral growth. However, the available literature evidence showed that the mutations in the catalytic site of tyrosine (Y203), methionine (M204), aspartic acid (D205) and aspartic acid (D206) will significantly reduce the efficacy of lamivudine and creates a resistance. In particular, M204V mutation affects the drug binding mechanism and cause resistance to lamivudine. Therefore, in the present study, we made an attempt to understand the mechanism of lamivudine resistance with the aid of computational techniques. The docking results suggest that lamivudine was found to adopt most promising conformations with native type HDP by identifying M204 as a prospective partner for making polar contacts as compared to the mutant type HDP. The molecular dynamic (MD) results showed that the average atom, especially atoms of the native-type HDP-lamivudine complex, movements were small, displayed fast convergence of energy and charges in geometry. This highlights the stable binding of the lamivudine with native-type HDP as compared to mutant type HDP. The normalized mean square displacement and root mean square fluctuation analysis certainly indicates conformational changes in the HDP structure due to M204V mutation. Furthermore, the hydrogen bond analysis from the MD study demonstrated that there is decreased number of intermolecular hydrogen bonds in mutant HDP-lamivudine complex than that in the native-type HDP-lamivudine complex.

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Computational model of hepatitis B virus DNA polymerase: Molecular dynamics and docking to understand resistant mutations

Cited by 38 publications

References 35 publications

Extensive Mutagenesis of the Conserved Box E Motif in Duck Hepatitis B Virus P Protein Reveals Multiple Functions in Replication and a Common Structure with the Primer Grip in HIV-1 Reverse Transcriptase

Extensive Mutagenesis of the Conserved Box E Motif in Duck Hepatitis B Virus P Protein Reveals Multiple Functions in Replication and a Common Structure with the Primer Grip in HIV-1 Reverse Transcriptase

Molecular Docking Study of Novel Anti-Hepatitis B Virus Agents Isolated from Talaromyces Species

Analysis of hepatitis B virus drug-resistant mutation (M204V) using molecular dynamics simulation techniques

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