Literature DB >> 19855131

Tregs control the development of symptomatic West Nile virus infection in humans and mice.

Marion C Lanteri1, Katie M O'Brien, Whitney E Purtha, Mark J Cameron, Jennifer M Lund, Rachel E Owen, John W Heitman, Brian Custer, Dale F Hirschkorn, Leslie H Tobler, Nancy Kiely, Harry E Prince, Lishomwa C Ndhlovu, Douglas F Nixon, Hany T Kamel, David J Kelvin, Michael P Busch, Alexander Y Rudensky, Michael S Diamond, Philip J Norris.   

Abstract

West Nile virus (WNV) causes asymptomatic infection in most humans, but for undefined reasons, approximately 20% of immunocompetent individuals develop West Nile fever, a potentially debilitating febrile illness, and approximately 1% develop neuroinvasive disease syndromes. Notably, since its emergence in 1999, WNV has become the leading cause of epidemic viral encephalitis in North America. We hypothesized that CD4+ Tregs might be differentially regulated in subjects with symptomatic compared with those with asymptomatic WNV infection. Here, we show that in 32 blood donors with acute WNV infection, Tregs expanded significantly in the 3 months after index (RNA+) donations in all subjects. Symptomatic donors exhibited lower Treg frequencies from 2 weeks through 1 year after index donation yet did not show differences in systemic T cell or generalized inflammatory responses. In parallel prospective experimental studies, symptomatic WNV-infected mice also developed lower Treg frequencies compared with asymptomatic mice at 2 weeks after infection. Moreover, Treg-deficient mice developed lethal WNV infection at a higher rate than controls. Together, these results suggest that higher levels of peripheral Tregs after infection protect against severe WNV disease in immunocompetent animals and humans.

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Year:  2009        PMID: 19855131      PMCID: PMC2769173          DOI: 10.1172/JCI39387

Source DB:  PubMed          Journal:  J Clin Invest        ISSN: 0021-9738            Impact factor:   14.808


  59 in total

1.  Foxp3 programs the development and function of CD4+CD25+ regulatory T cells.

Authors:  Jason D Fontenot; Marc A Gavin; Alexander Y Rudensky
Journal:  Nat Immunol       Date:  2003-03-03       Impact factor: 25.606

2.  Associations between West Nile virus infection and symptoms reported by blood donors identified through nucleic acid test screening.

Authors:  Brian Custer; Hany Kamel; Nancy E Kiely; Edward L Murphy; Michael P Busch
Journal:  Transfusion       Date:  2009-02       Impact factor: 3.157

3.  Transmission of West Nile virus through blood transfusion in the United States in 2002.

Authors:  Lisa N Pealer; Anthony A Marfin; Lyle R Petersen; Robert S Lanciotti; Peter L Page; Susan L Stramer; Mary Grace Stobierski; Kimberly Signs; Bruce Newman; Hema Kapoor; Jesse L Goodman; Mary E Chamberland
Journal:  N Engl J Med       Date:  2003-09-18       Impact factor: 91.245

4.  B cells and antibody play critical roles in the immediate defense of disseminated infection by West Nile encephalitis virus.

Authors:  Michael S Diamond; Bimmi Shrestha; Anantha Marri; Darby Mahan; Michael Engle
Journal:  J Virol       Date:  2003-02       Impact factor: 5.103

5.  IFN-gamma-producing gamma delta T cells help control murine West Nile virus infection.

Authors:  Tian Wang; Eileen Scully; Zhinan Yin; Jung H Kim; Sha Wang; Jun Yan; Mark Mamula; John F Anderson; Joe Craft; Erol Fikrig
Journal:  J Immunol       Date:  2003-09-01       Impact factor: 5.422

6.  Prophylactic and therapeutic efficacy of human intravenous immunoglobulin in treating West Nile virus infection in mice.

Authors:  David Ben-Nathan; Shlomo Lustig; Guy Tam; Shahar Robinzon; Shraga Segal; Bracha Rager-Zisman
Journal:  J Infect Dis       Date:  2003-06-23       Impact factor: 5.226

7.  Suppression of HCV-specific T cells without differential hierarchy demonstrated ex vivo in persistent HCV infection.

Authors:  Kazushi Sugimoto; Fusao Ikeda; Jason Stadanlick; Frederick A Nunes; Harvey J Alter; Kyong-Mi Chang
Journal:  Hepatology       Date:  2003-12       Impact factor: 17.425

8.  Certified professionals: CD4(+)CD25(+) suppressor T cells.

Authors:  E M Shevach
Journal:  J Exp Med       Date:  2001-06-04       Impact factor: 14.307

9.  Interleukin 2 signaling is required for CD4(+) regulatory T cell function.

Authors:  Gláucia C Furtado; Maria A Curotto de Lafaille; Nino Kutchukhidze; Juan J Lafaille
Journal:  J Exp Med       Date:  2002-09-16       Impact factor: 14.307

10.  CD4+CD25+ T cells regulate virus-specific primary and memory CD8+ T cell responses.

Authors:  Susmit Suvas; Uday Kumaraguru; Christopher D Pack; Sujin Lee; Barry T Rouse
Journal:  J Exp Med       Date:  2003-09-15       Impact factor: 14.307
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  137 in total

Review 1.  Plasticity in programming of effector and memory CD8 T-cell formation.

Authors:  Ramon Arens; Stephen P Schoenberger
Journal:  Immunol Rev       Date:  2010-05       Impact factor: 12.988

2.  Epitope-specific regulatory CD4 T cells reduce virus-induced illness while preserving CD8 T-cell effector function at the site of infection.

Authors:  Jie Liu; Tracy J Ruckwardt; Man Chen; John D Nicewonger; Teresa R Johnson; Barney S Graham
Journal:  J Virol       Date:  2010-08-04       Impact factor: 5.103

Review 3.  How tolerogenic dendritic cells induce regulatory T cells.

Authors:  Roberto A Maldonado; Ulrich H von Andrian
Journal:  Adv Immunol       Date:  2010       Impact factor: 3.543

4.  NIAID workshop on Flavivirus immunity.

Authors:  Alison D Augustine; M Cristina Cassetti; Francis A Ennis; Eva Harris; William H Hildebrand; Patricia M Repik
Journal:  Viral Immunol       Date:  2010-06       Impact factor: 2.257

5.  Altered profile of regulatory T cells and associated cytokines in mild and moderate dengue.

Authors:  H Tillu; A S Tripathy; P V Reshmi; D Cecilia
Journal:  Eur J Clin Microbiol Infect Dis       Date:  2016-02-09       Impact factor: 3.267

Review 6.  Some unmet challenges in the immunology of viral infections.

Authors:  Barry T Rouse; Aron E Lukacher
Journal:  Discov Med       Date:  2010-10       Impact factor: 2.970

7.  CD4+ T cells are not required for the induction of dengue virus-specific CD8+ T cell or antibody responses but contribute to protection after vaccination.

Authors:  Lauren E Yauch; Tyler R Prestwood; Monica M May; Malika M Morar; Raphaël M Zellweger; Bjoern Peters; Alessandro Sette; Sujan Shresta
Journal:  J Immunol       Date:  2010-09-24       Impact factor: 5.422

Review 8.  West Nile Virus: biology, transmission, and human infection.

Authors:  Tonya M Colpitts; Michael J Conway; Ruth R Montgomery; Erol Fikrig
Journal:  Clin Microbiol Rev       Date:  2012-10       Impact factor: 26.132

Review 9.  West Nile virus infection and immunity.

Authors:  Mehul S Suthar; Michael S Diamond; Michael Gale
Journal:  Nat Rev Microbiol       Date:  2013-02       Impact factor: 60.633

Review 10.  The Immune Fulcrum: Regulatory T Cells Tip the Balance Between Pro- and Anti-inflammatory Outcomes upon Infection.

Authors:  Laura E Richert-Spuhler; Jennifer M Lund
Journal:  Prog Mol Biol Transl Sci       Date:  2015-08-18       Impact factor: 3.622
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