Evolutionarily divergent herpesviruses modulate T cell activation by targeting the herpesvirus entry mediator cosignaling pathway
about
Modulation of tumor necrosis factor by microbial pathogens.The human cytomegalovirus UL11 protein interacts with the receptor tyrosine phosphatase CD45, resulting in functional paralysis of T cellsThe UL144 gene product of human cytomegalovirus activates NFkappaB via a TRAF6-dependent mechanismThe genetics of complex cholestatic disordersBTLA interaction with HVEM expressed on CD8(+) T cells promotes survival and memory generation in response to a bacterial infectionStructure of human cytomegalovirus UL141 binding to TRAIL-R2 reveals novel, non-canonical death receptor interactionsT cell intrinsic heterodimeric complexes between HVEM and BTLA determine receptivity to the surrounding microenvironment.High-throughput sequence analysis of variants of human cytomegalovirus strains Towne and AD169.T follicular helper expansion and humoral-mediated rejection are independent of the HVEM/BTLA pathwayCharacterization of the transcripts of human cytomegalovirus UL144.The LIGHT and DARC sides of herpesvirus entry mediatorLimited dissemination and shedding of the UL128 complex-intact, UL/b'-defective rhesus cytomegalovirus strain 180.92Polymorphic variants of LIGHT (TNF superfamily-14) alter receptor avidity and bioavailability.Herpes virus entry mediator (HVEM) modulates proliferation and activation of regulatory T cells following HSV-1 infectionHerpes simplex virus glycoprotein D interferes with binding of herpesvirus entry mediator to its ligands through downregulation and direct competitionAttenuating lymphocyte activity: the crystal structure of the BTLA-HVEM complex.Human cytomegalovirus UL144 is associated with viremia and infant development sequelae in congenital infectionImmunomodulatory Functions of BTLA and HVEM Govern Induction of Extrathymic Regulatory T Cells and Tolerance by Dendritic Cells.Dendritic cell programming by cytomegalovirus stunts naive T cell responses via the PD-L1/PD-1 pathway.Expression of the human cytomegalovirus UL11 glycoprotein in viral infection and evaluation of its effect on virus-specific CD8 T cells.Regulation of inflammation, autoimmunity, and infection immunity by HVEM-BTLA signaling.MicroRNA regulate immune pathways in T-cells in multiple sclerosis (MS).Forced LIGHT expression in prostate tumors overcomes Treg mediated immunosuppression and synergizes with a prostate tumor therapeutic vaccine by recruiting effector T lymphocytes.CD8 T cell memory to a viral pathogen requires trans cosignaling between HVEM and BTLA.Open reading frames carried on UL/b' are implicated in shedding and horizontal transmission of rhesus cytomegalovirus in rhesus monkeys.CD160 is essential for NK-mediated IFN-γ productionTumor necrosis factor superfamily in innate immunity and inflammation.Infection history determines the differentiation state of human CD8+ T cellsTNF Superfamily Networks: bidirectional and interference pathways of the herpesvirus entry mediator (TNFSF14)The role of coinhibitory signaling pathways in transplantation and toleranceThe Expression of BTLA Was Increased and the Expression of HVEM and LIGHT Were Decreased in the T Cells of Patients with Rheumatoid Arthritis [corrected]The signaling networks of the herpesvirus entry mediator (TNFRSF14) in immune regulationHerpesvirus entry mediator on radiation-resistant cell lineages promotes ocular herpes simplex virus 1 pathogenesis in an entry-independent manner.Immunoregulation by tumor necrosis factor superfamily member LIGHTPolymorphisms and features of cytomegalovirus UL144 and UL146 in congenitally infected neonates with hepatic involvement.The immunology of human cytomegalovirus latency: could latent infection be cleared by novel immunotherapeutic strategies?Insights into the mechanisms of CMV-mediated interference with cellular apoptosis.The canonical and unconventional ligands of the herpesvirus entry mediatorHuman cytomegalovirus encoded homologs of cytokines, chemokines and their receptors: roles in immunomodulation.Coding potential of UL/b' from the initial source of rhesus cytomegalovirus Strain 68-1.
P2860
Q21089629-62F5AF52-F45B-400A-9244-12AC7E128587Q21090492-E921F67A-09B0-4F28-9CD9-162D3B1F25C1Q24300688-ADBB635C-50A2-4EC0-B397-03331297019EQ26992279-D0D0B086-4C54-403F-BB91-C2BF34B5F075Q27303620-E4E1836C-9D1F-482E-9841-9A78B02A851CQ27677202-EBA31508-4B82-4CFF-B1FD-8113D564227DQ33832366-65872C25-3F7C-4822-ABBF-EDD6F0CF2D33Q33913596-24B7441F-D137-4F35-B2BF-F5DD08609591Q33920121-F5BF15D8-6A89-4CCD-B554-182714FD8385Q33931137-C3255D45-65A4-4764-A61E-776FE4767F9AQ34016123-118F1EB0-4CD2-452C-804B-D739BE92F7F8Q34059228-DDCA5353-62C9-4C78-9001-9F9938736FF0Q34065607-8752693B-3537-442E-8F2A-5D35893FFD14Q34115308-40B552C9-F03F-44BF-80C4-30A01D1D5BC4Q34295959-6F326E10-1D03-43D3-B7F4-AAD3D9FCF313Q34451878-7800ED95-486F-4EF8-A0EC-C28AC611FD4CQ34489526-F22E155D-F458-44BD-9B0A-A4F23F40319BQ34543668-5A328D3C-7F7C-4FE9-96AC-7A18CEF76AE5Q34589567-33DF5FC4-3437-4D64-B7B2-373DF32D86E1Q34594928-300903F7-56E9-47C9-AEC7-695748A9929CQ34683637-6BF322C8-D6FE-4DCB-BEEE-62F2C08522CFQ34878368-A5EBB31C-4845-402D-8996-0175A8398C00Q35013272-75A47C35-3AA7-4AD6-B72D-BE984E237076Q35035884-827F9444-FADE-4420-BCA7-1450B8DE841FQ35076699-349B0B5D-F658-4C6A-8BDC-1D3C050156B8Q35161483-51E11A5C-AC0F-4278-9964-CA2C0EA8C224Q35245316-70D15825-FC3F-4CF9-B0AD-760DB688EF35Q35488692-F3E95E05-4CCA-4631-9637-0CFC4BFAEF46Q35567956-1F5B21E9-E8CD-4793-B53A-9864E26A81B5Q35928357-A7D43D55-9083-44C5-946C-83C30B4B18CDQ36018649-F7E78574-17ED-4AEE-9179-F3C3D85A4A59Q36053977-F4CB0F32-E097-4D9D-BDDD-6E2A4D30DCCCQ36205873-B29EB00F-62AC-4CCE-9311-590C1D5571C9Q36253506-F93FCFBB-B915-49E5-BD13-4BCA1D2826BDQ36286363-2D093408-CCCB-4769-B659-253025B0EBBEQ36302615-BC4D2F1B-66ED-46C8-9D8F-361DE2700D27Q36365508-10DB8C79-9727-4AAB-99FD-22308E9E86FFQ36382858-AF3DDAB1-F4B8-487B-BCCA-3AC2BD50B4C7Q36432667-3E7C2552-E996-40A3-95F2-72176CAC56C5Q36685041-BD1D1BEB-F369-4B77-AA4C-50A911894C34
P2860
Evolutionarily divergent herpesviruses modulate T cell activation by targeting the herpesvirus entry mediator cosignaling pathway
description
2005 nî lūn-bûn
@nan
2005 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2005 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
name
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@ast
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en-gb
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@nl
type
label
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@ast
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en-gb
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@nl
prefLabel
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@ast
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en-gb
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@nl
P2093
P2860
P3181
P356
P1476
Evolutionarily divergent herpe ...... y mediator cosignaling pathway
@en
P2093
Bonnie R Tran
Carl F Ware
Chris A Benedict
Ginelle Patterson
Heather M Shumway
Karen G Potter
Kenneth M Murphy
Nell S Lurain
Patricia G Spear
P2860
P304
13218-13223
P3181
P356
10.1073/PNAS.0506172102
P407
P577
2005-08-30T00:00:00Z