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Literature DB >> 24178712

The innate immune playbook for restricting West Nile virus infection.

Abstract

West Nile virus (WNV) is an emerging mosquito-borne flavivirus that causes annual epidemics of encephalitic disease throughout the world. Despite the ongoing risk to public health, no approved vaccines or therapies exist for use in humans to prevent or combat WNV infection. The innate immune response is critical for controlling WNV replication, limiting virus-induced pathology, and programming protective humoral and cell-mediated immunity to WNV infection. The RIG-I like receptors, Toll-like receptors, and Nod-like receptors detect and respond to WNV by inducing a potent antiviral defense program, characterized by production of type I IFN, IL-1β and expression of antiviral effector genes. Recent research efforts have focused on uncovering the mechanisms of innate immune sensing, antiviral effector genes that inhibit WNV, and countermeasures employed by WNV to antagonize innate immune cellular defenses. In this review, we highlight the major research findings pertaining to innate immune regulation of WNV infection.

Entities: Chemical Disease Gene Species

Mesh：

Year: 2013 PMID： 24178712 PMCID： PMC3856407 DOI： 10.3390/v5112643

Source DB: PubMed Journal: Viruses ISSN： 1999-4915 Impact factor: 5.048

97 in total

1. A role for Ifit2 in restricting West Nile virus infection in the brain.

Authors: Hyelim Cho; Bimmi Shrestha; Ganes C Sen; Michael S Diamond
Journal: J Virol Date: 2013-06-05 Impact factor: 5.103

2. ATF6 signaling is required for efficient West Nile virus replication by promoting cell survival and inhibition of innate immune responses.

Authors: Rebecca L Ambrose; Jason M Mackenzie
Journal: J Virol Date: 2012-12-05 Impact factor: 5.103

3. Dephosphorylation of the RNA sensors RIG-I and MDA5 by the phosphatase PP1 is essential for innate immune signaling.

Authors: Effi Wies; May K Wang; Natalya P Maharaj; Kan Chen; Shenghua Zhou; Robert W Finberg; Michaela U Gack
Journal: Immunity Date: 2013-03-14 Impact factor: 31.745

4. Inflammasome adaptor protein Apoptosis-associated speck-like protein containing CARD (ASC) is critical for the immune response and survival in west Nile virus encephalitis.

Authors: Mukesh Kumar; Kelsey Roe; Beverly Orillo; Daniel A Muruve; Vivek R Nerurkar; Michael Gale; Saguna Verma
Journal: J Virol Date: 2013-01-09 Impact factor: 5.103

5. A systems biology approach reveals that tissue tropism to West Nile virus is regulated by antiviral genes and innate immune cellular processes.

Authors: Mehul S Suthar; Margaret M Brassil; Gabriele Blahnik; Aimee McMillan; Hilario J Ramos; Sean C Proll; Sarah E Belisle; Michael G Katze; Michael Gale
Journal: PLoS Pathog Date: 2013-02-07 Impact factor: 6.823

6. Differential innate immune response programs in neuronal subtypes determine susceptibility to infection in the brain by positive-stranded RNA viruses.

Authors: Hyelim Cho; Sean C Proll; Kristy J Szretter; Michael G Katze; Michael Gale; Michael S Diamond
Journal: Nat Med Date: 2013-03-03 Impact factor: 53.440

7. Viperin is induced following dengue virus type-2 (DENV-2) infection and has anti-viral actions requiring the C-terminal end of viperin.

Authors: Karla J Helbig; Jillian M Carr; Julie K Calvert; Satiya Wati; Jennifer N Clarke; Nicholas S Eyre; Sumudu K Narayana; Guillaume N Fiches; Erin M McCartney; Michael R Beard
Journal: PLoS Negl Trop Dis Date: 2013-04-18

8. A short hairpin RNA screen of interferon-stimulated genes identifies a novel negative regulator of the cellular antiviral response.

Authors: Jianqing Li; Steve C Ding; Hyelim Cho; Brian C Chung; Michael Gale; Sumit K Chanda; Michael S Diamond
Journal: MBio Date: 2013-06-18 Impact factor: 7.867

9. IFITM1 is a tight junction protein that inhibits hepatitis C virus entry.

Authors: Courtney Wilkins; Jessica Woodward; Daryl T-Y Lau; Amy Barnes; Michael Joyce; Nicola McFarlane; Jane A McKeating; D Lorne Tyrrell; Michael Gale
Journal: Hepatology Date: 2012-12-12 Impact factor: 17.425

10. IL-1R1 is required for dendritic cell-mediated T cell reactivation within the CNS during West Nile virus encephalitis.

Authors: Douglas M Durrant; Michelle L Robinette; Robyn S Klein
Journal: J Exp Med Date: 2013-03-04 Impact factor: 14.307

23 in total

Review 1. The tortoise or the hare? Impacts of within-host dynamics on transmission success of arthropod-borne viruses.

Authors: Benjamin M Althouse; Kathryn A Hanley
Journal: Philos Trans R Soc Lond B Biol Sci Date: 2015-08-19 Impact factor: 6.237

2. West Nile Virus-Inclusive Single-Cell RNA Sequencing Reveals Heterogeneity in the Type I Interferon Response within Single Cells.

Authors: Justin T O'Neal; Amit A Upadhyay; Amber Wolabaugh; Nirav B Patel; Steven E Bosinger; Mehul S Suthar
Journal: J Virol Date: 2019-03-05 Impact factor: 5.103

3. Associations between the presence of specific antibodies to the West Nile Virus infection and candidate genes in Romanian horses from the Danube delta.

Authors: K Stejskalova; E Janova; C Horecky; E Horecka; P Vaclavek; Z Hubalek; K Relling; M Cvanova; G D'Amico; A D Mihalca; D Modry; A Knoll; P Horin
Journal: Mol Biol Rep Date: 2019-06-07 Impact factor: 2.316

The innate immune playbook for restricting West Nile virus infection.

1. A role for Ifit2 in restricting West Nile virus infection in the brain.

2. ATF6 signaling is required for efficient West Nile virus replication by promoting cell survival and inhibition of innate immune responses.

3. Dephosphorylation of the RNA sensors RIG-I and MDA5 by the phosphatase PP1 is essential for innate immune signaling.

4. Inflammasome adaptor protein Apoptosis-associated speck-like protein containing CARD (ASC) is critical for the immune response and survival in west Nile virus encephalitis.

5. A systems biology approach reveals that tissue tropism to West Nile virus is regulated by antiviral genes and innate immune cellular processes.

6. Differential innate immune response programs in neuronal subtypes determine susceptibility to infection in the brain by positive-stranded RNA viruses.

7. Viperin is induced following dengue virus type-2 (DENV-2) infection and has anti-viral actions requiring the C-terminal end of viperin.

8. A short hairpin RNA screen of interferon-stimulated genes identifies a novel negative regulator of the cellular antiviral response.

9. IFITM1 is a tight junction protein that inhibits hepatitis C virus entry.

10. IL-1R1 is required for dendritic cell-mediated T cell reactivation within the CNS during West Nile virus encephalitis.

Review 1. The tortoise or the hare? Impacts of within-host dynamics on transmission success of arthropod-borne viruses.

2. West Nile Virus-Inclusive Single-Cell RNA Sequencing Reveals Heterogeneity in the Type I Interferon Response within Single Cells.

3. Associations between the presence of specific antibodies to the West Nile Virus infection and candidate genes in Romanian horses from the Danube delta.

Review 4. Zika Virus: Immunity and Vaccine Development.

Review 5. Current developments in understanding of West Nile virus central nervous system disease.

6. Immune responses of ducks infected with duck Tembusu virus.

Review 7. The pathogenesis of microcephaly resulting from congenital infections: why is my baby's head so small?

Review 8. Mechanisms of innate immune evasion in re-emerging RNA viruses.

Review 9. Utility, limitations, and future of non-human primates for dengue research and vaccine development.

Review 10. Encephalitic Arboviruses: Emergence, Clinical Presentation, and Neuropathogenesis.