Literature DB >> 18841330

Tick-borne flaviviruses: dissecting host immune responses and virus countermeasures.

Shelly J Robertson1, Dana N Mitzel, R Travis Taylor, Sonja M Best, Marshall E Bloom.   

Abstract

The tick-borne encephalitis (TBE) serocomplex of viruses, genus Flavivirus, includes a number of important human pathogens that cause serious neurological illnesses and hemorrhagic fevers. These viruses pose a significant public health problem due to high rates of morbidity and mortality, their emergence to new geographic areas, and the recent rise in the incidence of human infections. The most notable member of the TBE serocomplex is tick-borne encephalitis virus (TBEV), a neurotropic flavivirus that causes debilitating and sometimes fatal encephalitis. Although effective prophylactic anti-TBEV vaccines have been developed, there is currently no specific treatment for infection. To identify new targets for therapeutical intervention, it is imperative to understand interactions between TBEV and the host immune response to infection. Interferon (IFN) has a critical role in controlling flavivirus replication. Dendritic cells (DCs) represent an early target of TBEV infection and are major producers of IFN. Thus, interactions between DCs, IFN responses, and the virus are likely to substantially influence the outcome of infection. Early IFN and DC responses are modulated not only by the virus, but also by the tick vector and immunomodulatory compounds of tick saliva inoculated with virus into the skin. Our laboratory is examining interactions between the triad of virus, tick vector, and mammalian host that contribute to the pathogenesis of tick-borne flaviviruses. This work will provide a more detailed understanding of early events in virus infection and their impact on flavivirus pathogenesis.

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Year:  2009        PMID: 18841330      PMCID: PMC2774773          DOI: 10.1007/s12026-008-8065-6

Source DB:  PubMed          Journal:  Immunol Res        ISSN: 0257-277X            Impact factor:   2.829


  70 in total

Review 1.  Molecular aspects of TBE virus research.

Authors:  Franz X Heinz
Journal:  Vaccine       Date:  2003-04-01       Impact factor: 3.641

2.  Type I interferon induction pathway, but not released interferon, participates in the maturation of dendritic cells induced by negative-strand RNA viruses.

Authors:  Carolina B López; Adolfo García-Sastre; Bryan R G Williams; Thomas M Moran
Journal:  J Infect Dis       Date:  2003-03-19       Impact factor: 5.226

Review 3.  Tick-borne encephalitis.

Authors:  T S Gritsun; V A Lashkevich; E A Gould
Journal:  Antiviral Res       Date:  2003-01       Impact factor: 5.970

4.  Nonstructural proteins 1 and 2 of respiratory syncytial virus suppress maturation of human dendritic cells.

Authors:  Shirin Munir; Cyril Le Nouen; Cindy Luongo; Ursula J Buchholz; Peter L Collins; Alexander Bukreyev
Journal:  J Virol       Date:  2008-06-18       Impact factor: 5.103

5.  Identification of genetic determinants of a tick-borne flavivirus associated with host-specific adaptation and pathogenicity.

Authors:  Dana N Mitzel; Sonja M Best; Max F Masnick; Stephen F Porcella; James B Wolfinbarger; Marshall E Bloom
Journal:  Virology       Date:  2008-09-26       Impact factor: 3.616

Review 6.  Architects of assembly: roles of Flaviviridae non-structural proteins in virion morphogenesis.

Authors:  Catherine L Murray; Christopher T Jones; Charles M Rice
Journal:  Nat Rev Microbiol       Date:  2008-09       Impact factor: 60.633

7.  DC-SIGN enhances infection of cells with glycosylated West Nile virus in vitro and virus replication in human dendritic cells induces production of IFN-alpha and TNF-alpha.

Authors:  Byron E E Martina; Penelopie Koraka; Petra van den Doel; Guus F Rimmelzwaan; Bart L Haagmans; Albert D M E Osterhaus
Journal:  Virus Res       Date:  2008-04-10       Impact factor: 3.303

8.  Positional cloning of the murine flavivirus resistance gene.

Authors:  Andrey A Perelygin; Svetlana V Scherbik; Igor B Zhulin; Bronislava M Stockman; Yan Li; Margo A Brinton
Journal:  Proc Natl Acad Sci U S A       Date:  2002-06-21       Impact factor: 11.205

Review 9.  Structural insights into the mechanisms of antibody-mediated neutralization of flavivirus infection: implications for vaccine development.

Authors:  Theodore C Pierson; Daved H Fremont; Richard J Kuhn; Michael S Diamond
Journal:  Cell Host Microbe       Date:  2008-09-11       Impact factor: 21.023

10.  Ticks produce highly selective chemokine binding proteins with antiinflammatory activity.

Authors:  Maud Déruaz; Achim Frauenschuh; Ana L Alessandri; João M Dias; Fernanda M Coelho; Remo C Russo; Beatriz R Ferreira; Gerard J Graham; Jeffrey P Shaw; Timothy N C Wells; Mauro M Teixeira; Christine A Power; Amanda E I Proudfoot
Journal:  J Exp Med       Date:  2008-08-04       Impact factor: 14.307
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  30 in total

1.  The neurovirulence and neuroinvasiveness of chimeric tick-borne encephalitis/dengue virus can be attenuated by introducing defined mutations into the envelope and NS5 protein genes and the 3' non-coding region of the genome.

Authors:  Amber R Engel; Alexander A Rumyantsev; Olga A Maximova; James M Speicher; Brian Heiss; Brian R Murphy; Alexander G Pletnev
Journal:  Virology       Date:  2010-07-01       Impact factor: 3.616

Review 2.  Smuggling across the border: how arthropod-borne pathogens evade and exploit the host defense system of the skin.

Authors:  Quentin Bernard; Benoit Jaulhac; Nathalie Boulanger
Journal:  J Invest Dermatol       Date:  2013-12-28       Impact factor: 8.551

3.  TRIM79α, an interferon-stimulated gene product, restricts tick-borne encephalitis virus replication by degrading the viral RNA polymerase.

Authors:  R Travis Taylor; Kirk J Lubick; Shelly J Robertson; James P Broughton; Marshall E Bloom; Wade A Bresnahan; Sonja M Best
Journal:  Cell Host Microbe       Date:  2011-09-15       Impact factor: 21.023

4.  Microarray hybridization for assessment of the genetic stability of chimeric West Nile/dengue 4 virus.

Authors:  Majid Laassri; Bella Bidzhieva; James Speicher; Alexander G Pletnev; Konstantin Chumakov
Journal:  J Med Virol       Date:  2011-02-25       Impact factor: 2.327

Review 5.  Tick-Borne Flaviviruses, with a Focus on Powassan Virus.

Authors:  Gábor Kemenesi; Krisztián Bányai
Journal:  Clin Microbiol Rev       Date:  2018-12-12       Impact factor: 26.132

6.  A functional Toll-like receptor 3 gene (TLR3) may be a risk factor for tick-borne encephalitis virus (TBEV) infection.

Authors:  Elin Kindberg; Sirkka Vene; Aukse Mickiene; Åke Lundkvist; Lars Lindquist; Lennart Svensson
Journal:  J Infect Dis       Date:  2011-01-07       Impact factor: 5.226

7.  Molecular Mechanisms of Interaction Between Human Immune Cells and Far Eastern Tick-Borne Encephalitis Virus Strains.

Authors:  Natalya V Krylova; Tatiana P Smolina; Galina N Leonova
Journal:  Viral Immunol       Date:  2015-02-19       Impact factor: 2.257

8.  Tick-borne encephalitis virus delays interferon induction and hides its double-stranded RNA in intracellular membrane vesicles.

Authors:  Anna K Overby; Vsevolod L Popov; Matthias Niedrig; Friedemann Weber
Journal:  J Virol       Date:  2010-06-16       Impact factor: 5.103

9.  Biological and genetic properties of SA₁₄-14-2, a live-attenuated Japanese encephalitis vaccine that is currently available for humans.

Authors:  Byung-Hak Song; Gil-Nam Yun; Jin-Kyoung Kim; Sang-Im Yun; Young-Min Lee
Journal:  J Microbiol       Date:  2012-08-25       Impact factor: 3.422

10.  TNF-α acts as an immunoregulator in the mouse brain by reducing the incidence of severe disease following Japanese encephalitis virus infection.

Authors:  Daisuke Hayasaka; Kenji Shirai; Kotaro Aoki; Noriyo Nagata; Dash Sima Simantini; Kazutaka Kitaura; Yuki Takamatsu; Ernest Gould; Ryuji Suzuki; Kouichi Morita
Journal:  PLoS One       Date:  2013-08-05       Impact factor: 3.240
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