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Role of core protein mutations in the development of occult HBV infection

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Role of core protein mutations in the development of occult HBV infection
  • Occult hepatitis B virus infection: implications in transfusion.

    Vox Sang. 2004; 86: 83-91

    • Raimondo G.
    • Allain J.P.
    • Brunetto M.R.
    • Buendia M.
    • Chen D.
    • Colombo M.
    • et al.

    Statements from the Taormina expert meeting on occult hepatitis B virus infection.

    J Hepatol. 2008; 49: 652-657

    • Raimondo G.
    • Locarnini S.
    • Pollicino T.
    • Levrero M.
    • Zoulim F.
    • Lok A.S.
    • et al.

    Update of the statements on biology and clinical impact of occult hepatitis B virus infection.

    J Hepatol. 2019; 71: 397-408

    • Zacharakis G.
    • Koskinas J.
    • Kotsiou S.
    • Tzara F.
    • Vafeiadis N.
    • Papoutselis M.
    • et al.

    The role of serial measurement of serum HBV DNA levels in patients with chronic HBeAg(−) hepatitis B infection: Association with liver disease progression. A prospective cohort study.

    J Hepatol. 2008; 49: 884-891

  • How reproducible are rat steatosis models using high-fat diets? Reply.

    J Hepatol. 2009; 51: 824

    • Wong D.K.
    • Huang F.Y.
    • Lai C.L.
    • Poon R.T.
    • Seto W.K.
    • Fung J.
    • et al.

    Occult hepatitis B infection and HBV replicative activity in patients with cryptogenic cause of hepatocellular carcinoma.

    Hepatology. 2011; 54: 829-836

    • Biswas S.
    • Candotti D.
    • Allain J.P.

    Specific Amino Acid Substitutions in the S Protein Prevent Its Excretion In Vitro and May Contribute to Occult Hepatitis B Virus Infection.

    J Virol. 2013; 87: 7882-7892

    • Huang C.
    • Yuan Q.
    • Chen P.
    • Zhang Y.
    • Chen C.
    • Zheng Q.
    • et al.

    Influence of mutations in hepatitis B virus surface protein on viral antigenicity and phenotype in occult HBV strains from blood donors.

    J Hepatol. 2012; 57: 720-729

    • El Chaar M.
    • Candotti D.
    • Crowther R.A.
    • Allain J.P.

    Impact of hepatitis B virus surface protein mutations on the diagnosis of occult hepatitis B virus infection.

    Hepatology. 2010; 52: 1600-1610

    • Chaudhuri V.
    • Tayal R.
    • Nayak B.
    • Acharya S.K.
    • Panda S.K.

    Occult hepatitis B virus infection in chronic liver disease: full-length genome and analysis of mutant surface promoter.

    Gastroenterology. 2004; 127: 1356-1371

    • Fang Y.
    • Teng X.
    • Xu W.Z.
    • Li D.
    • Zhao H.W.
    • Fu L.J.
    • et al.

    Molecular characterization and functional analysis of occult hepatitis B virus infection in Chinese patients infected with genotype C.

    J. Med. Virol. 2009; 81: 826-835

    • Pollicino T.
    • Raffa G.
    • Costantino L.
    • Lisa A.
    • Campello C.
    • Squadrito G.
    • et al.

    Molecular and functional analysis of occult hepatitis B virus isolates from patients with hepatocellular carcinoma.

    Hepatology. 2007; 45: 277-285

    • Candotti D.
    • Grabarczyk P.
    • Ghiazza P.
    • Roig R.
    • Casamitjana N.
    • Iudicone P.
    • et al.

    Characterization of occult hepatitis B virus from blood donors carrying genotype A2 or genotype D strains.

    J Hepatol. 2008; 49: 537-547

    • Chang C.
    • Enders G.
    • Sprengel R.
    • Peters N.
    • Varmus H.E.
    • Ganem D.

    Expression of the precore region of an avian hepatitis B virus is not required for viral replication.

    J Virol. 1987; 61: 3322-3325

    • Schlicht H.J.
    • Salfeld J.
    • Schaller H.

    The duck hepatitis B virus pre-C region encodes a signal sequence which is essential for synthesis and secretion of processed core proteins but not for virus formation.

    J Virol. 1987; 61: 3701-3709

    • Chen H.S.
    • Kew M.C.
    • Hornbuckle W.E.
    • Tennant B.C.
    • Cote P.J.
    • Gerin J.L.
    • et al.

    The precore gene of the woodchuck hepatitis virus genome is not essential for viral replication in the natural host.

    J Virol. 1992; 66: 5682-5684

  • Molecular biology of hepatitis B virus e antigen.

    J Gastroenterol Hepatol. 1997; 12: S178-187

  • Exploring the biological basis of hepatitis B e antigen in hepatitis B virus infection.

    Hepatology. 2003; 38: 1075-1086

    • Yang C.Y.
    • Kuo T.H.
    • Ting L.P.

    Human hepatitis B viral e antigen interacts with cellular interleukin-1 receptor accessory protein and triggers interleukin-1 response.

    J Biol Chem. 2006; 281: 34525-34536

    • Al-Qahtani A.A.
    • Al-Anazi M.R.
    • Nazir N.
    • Abdo A.A.
    • Sanai F.M.
    • Al-Hamoudi W.K.
    • et al.

    The correlation between hepatitis B virus precore/core mutations and the progression of severe liver disease.

    Front Cell Infect Mi. 2018; 8: 355

    • Zheng X.
    • Ye X.
    • Zhang L.
    • Wang W.
    • Shuai L.
    • Wang A.
    • et al.

    Characterization of Occult Hepatitis B virus Infection from Blood Donors in China.

    J Clin Microbiol. 2011; 49: 1730-1737

    • Wang Z.
    • Zeng J.
    • Li T.
    • Zheng X.
    • Xu X.
    • Ye X.
    • et al.

    Prevalence of hepatitis B surface antigen (HBsAg) in a blood donor population born prior to and after implementation of universal HBV vaccination in Shenzhen, China.

    BMC Infect Dis. 2016; 16: 498

    • Wang J.
    • Zhang P.
    • Zeng J.
    • Du P.
    • Zheng X.
    • Ye X.
    • et al.

    Occurrence of occult hepatitis B virus infection associated with envelope protein mutations according to anti-HBs carriage in blood donors.

    Int J Infect Dis. 2020; 92: 38-45

    • Guo H.
    • Zhou T.
    • Jiang D.
    • Cuconati A.
    • Xiao G.H.
    • Block T.M.
    • Guo J.T.

    Regulation of hepatitis B virus replication by the phosphatidylinositol 3-kinase-akt signal transduction pathway.

    J Virol. 2007; 81: 10072-10080

    • Wang J.
    • Shen T.
    • Huang X.
    • Kumar G.R.
    • Chen X.
    • Zeng Z.
    • et al.

    Serum hepatitis B virus RNA is encapsidated pregenome RNA that may be associated with persistence of viral infection and rebound.

    J Hepatol. 2016; 65: 700-710

    • Li T.
    • Zhu S.
    • Shuai L.
    • Xu Y.
    • Yin S.
    • Bian Y.
    • Wang Y.
    • et al.

    Infection of common marmosets with hepatitis C virus/GB virus-B chimeras.

    Hepatology. 2014; 59: 789-802

    • Watts N.R.
    • Conway J.F.
    • Cheng N.
    • Stahl S.J.
    • Steven A.C.
    • Wingfield P.T.

    Role of the propeptide in controlling conformation and assembly state of hepatitis B virus e-antigen.

    J Mol Biol. 2011; 409: 202-213

    • Zlotnick A.
    • Tan Z.
    • Selzer L.

    One protein, at least three structures, and many functions.

    Structure. 2013; 21: 6-8

    • Tan Z.
    • Pionek K.
    • Unchwaniwala N.
    • Maguire M.L.
    • Loeb D.D.
    • Zlotnick A.

    The interface between hepatitis B virus capsid proteins affects self-assembly, pregenomic RNA packaging, and reverse transcription.

    J Virol. 2015; 89: 3275-3284

    • Ludgate L.
    • Liu K.
    • Luckenbaugh L.
    • Streck N.
    • Eng S.
    • Voitenleitner C.
    • et al.

    Cell-free hepatitis B virus capsid assembly dependent on the core protein C-terminal domain and regulated by phosphorylation.

    J Virol. 2016; 90: 5830-5844

    • Alexander C.G.
    • Jürgens M.C.
    • Shepherd D.A.
    • Freund S.M.
    • Ashcroft A.E.
    • Ferguson N.

    Thermodynamic origins of protein folding, allostery, and capsid formation in the human hepatitis B virus core protein.

    Proc Natl Acad Sci U S A. 2013; 110: E2782-2791

    • Selzer L.
    • Katen S.P.
    • Zlotnick A.

    The hepatitis B virus core protein intradimer interface modulates capsid assembly and stability.

    Biochemistry. 2014; 53: 5496-5504

  • Naturally occurring hepatitis B virus core gene mutations.

    Hepatology. 1995; 22: 50-60

    • Le Pogam S.
    • Yuan T.T.
    • Sahu G.K.
    • Chatterjee S.
    • Shih C.

    Low-level secretion of human hepatitis B virus virions caused by two independent, naturally occurring mutations (P5T and L60V) in the capsid protein.

    J Virol. 2000; 74: 9099-9105

  • Mapping of amino acid side chains on the surface of hepatitis B virus capsids required for envelopment and virion formation.

    J Virol. 2003; 77: 416-422

    • Cui X.
    • Luckenbaugh L.
    • Bruss V.
    • Hu J.

    Alteration of mature nucleocapsid and enhancement of covalently closed circular DNA formation by hepatitis B virus core mutants defective in complete-virion formation.

    J Virol. 2015; 89: 10064-10072

    • Ning X.
    • Luckenbaugh L.
    • Liu K.
    • Bruss V.
    • Sureau C.
    • Hu J.

    Common and Distinct Capsid and Surface Protein Requirements for Secretion of Complete and Genome-Free Hepatitis B Virions.

    J Virol. 2018; 92 ()

    • Kang H.Y.
    • Lee S.
    • Park S.G.
    • Yu J.
    • Kim Y.
    • Jung G.

    Phosphorylation of hepatitis B virus Cp at Ser87 facilitates core assembly.

    Biochem J. 2006; 398: 311-317

    • Ceres P.
    • Stray S.J.
    • Zlotnick A.

    Hepatitis B virus capsid assembly is enhanced by naturally occurring mutation F97L.

    J Virol. 2004; 78: 9538-9543

    • Suk F.M.
    • Lin M.H.
    • Newman M.
    • Pan S.
    • Chen S.H.
    • Liu J.D.
    • Shih C.

    Replication advantage and host factor-independent phenotypes attributable to a common naturally occurring capsid mutation (I97L) in human hepatitis B virus.

    J Virol. 2002; 76: 12069-12077

  • Nucleolar localization of human hepatitis B virus capsid protein.

    J Virol. 2004; 78: 13653-13668

    • Wang J.
    • Zhang H.
    • Zhang Y.
    • Jiang D.
    • Li J.
    • Goldmann S.
    • et al.

    Influences on viral replication and sensitivity to GLS4, a HAP compound, of naturally occurring T109/V124 mutations in hepatitis B virus core protein.

    J Med Virol. 2017; 89: 1804-1810

    • Tan Z.
    • Maguire M.L.
    • Loeb D.D.
    • Zlotnick A.

    Genetically altering the thermodynamics and kinetics of hepatitis B virus capsid assembly has profound effects on virus replication in cell culture.

    J Virol. 2013; 87: 3208-3216

    • Jung J.
    • Hwang S.G.
    • Chwae Y.J.
    • Park S.
    • Shin H.J.
    • Kim K.

    Phosphoacceptors threonine 162 and serines 170 and 178 within the carboxyl-terminal RRRS/T motif of the hepatitis B virus core protein make multiple contributions to hepatitis B virus replication.

    J Virol. 2014; 88: 8754-8767

    • Imai M.
    • Nomura M.
    • Gotanda T.
    • Sano T.
    • Tachibana K.
    • Miyamoto H.
    • et al.

    Demonstration of two distinct antigenic determinants on hepatitis B e antigen by monoclonal antibodies.

    J Immunol. 1982; 128: 69-72

    • Kim D.W.
    • Lee S.A.
    • Hwang E.S.
    • Kook Y.H.
    • Kim B.J.

    Naturally occurring precore/core region mutations of hepatitis B virus genotype C related to hepatocellular carcinoma.

    PLoS One. 2012; 7e47372

    • Frelin L.
    • Wahlstrom T.
    • Tucker A.E.
    • Jones J.
    • Hughes J.
    • Lee B.O.
    • et al.

    A Mechanism To Explain the selection of the hepatitis e antigen-negative mutant during chronic hepatitis B virus infection.

    J Virol. 2009; 83: 1379-1392

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