Immunofluorescence analysis of poliovirus receptor expression in Peyer's patches of humans, primates, and CD155 transgenic mice: implications for poliovirus infection.
about
The alpha/beta interferon response controls tissue tropism and pathogenicity of poliovirus.Establishment of a poliovirus oral infection system in human poliovirus receptor-expressing transgenic mice that are deficient in alpha/beta interferon receptorIncreased CD112 expression in methylcholanthrene-induced tumors in CD155-deficient miceTick-borne encephalitis virus replication, intracellular trafficking, and pathogenicity in human intestinal Caco-2 cell monolayersRecruitment of nectin-3 to cell-cell junctions through trans-heterophilic interaction with CD155, a vitronectin and poliovirus receptor that localizes to alpha(v)beta3 integrin-containing membrane microdomainsImmunology of Gut Mucosal VaccinesEnteroviruses harness the cellular endocytic machinery to remodel the host cell cholesterol landscape for effective viral replication.Poliomyelitis in transgenic mice expressing CD155 under the control of the Tage4 promoter after oral and parenteral poliovirus inoculationMutation of a single conserved nucleotide between the cloverleaf and internal ribosome entry site attenuates poliovirus neurovirulenceCritical role of DNAX accessory molecule-1 (DNAM-1) in the development of acute graft-versus-host disease in miceRole of the alpha/beta interferon response in the acquisition of susceptibility to poliovirus by kidney cells in culture.A host-specific, temperature-sensitive translation defect determines the attenuation phenotype of a human rhinovirus/poliovirus chimera, PV1(RIPO).Expression of human decay-accelerating factor on intestinal epithelium of transgenic mice does not facilitate infection by the enteral routePoliovirus trafficking toward central nervous system via human poliovirus receptor-dependent and -independent pathway.Increased Soluble CD155 in the Serum of Cancer Patients.Host and virus determinants of picornavirus pathogenesis and tropism.Follicular dendritic cell networks of primary follicles and germinal centers: phenotype and functionCharacterization of the New World monkey homologues of human poliovirus receptor CD155.In vivo role of nectin-1 in entry of herpes simplex virus type 1 (HSV-1) and HSV-2 through the vaginal mucosa.Accelerated tumor growth in mice deficient in DNAM-1 receptorFuture of polio vaccines.Innate host barriers to viral trafficking and population diversity: lessons learned from poliovirus.Caspase-8 and FLIP regulate RIG-I/MDA5-induced innate immune host responses to picornaviruses.Validation of an Immunohistochemistry Assay for Detection of CD155, the Poliovirus Receptor, in Malignant Gliomas.Oncolytic poliovirus against malignant glioma.Negative immune checkpoints on T lymphocytes and their relevance to cancer immunotherapy.Intestinal M cells.Enteroviral proteases: structure, host interactions and pathogenicity.Mammalian Lipopolysaccharide Receptors Incorporated into the Retroviral Envelope Augment Virus Transmission.Co-inhibitory blockade while preserving tolerance: checkpoint inhibitors for glioblastoma.Pathogenic Events in a Nonhuman Primate Model of Oral Poliovirus Infection Leading to Paralytic Poliomyelitis.UPR decreases CD226 ligand CD155 expression and sensitivity to NK cell-mediated cytotoxicity in hepatoma cells.CEACAM2-L on spermatids interacts with poliovirus receptor on Sertoli cells in mouse seminiferous epithelium.Perinatal characteristics and risk of polio among Swedish twins.Interactions between Enteric Bacteria and Eukaryotic Viruses Impact the Outcome of Infection.Cd226-/- natural killer cells fail to establish stable contacts with cancer cells and show impaired control of tumor metastasis in vivo.Recombinant Poliovirus for Cancer Immunotherapy.High detection frequency and viral loads of human rhinovirus species A to C in fecal samples; diagnostic and clinical implications.Poliomyelitis era in Trinidad from 1940 to 1972 and beyond: Implications for effective global health governance for its eradicationSelective DNAM-1 expression on small peritoneal macrophages contributes to CD4 T cell costimulation
P2860
Q24519073-C5382641-E15E-4481-AD87-45D5D174F648Q24676247-87398447-CA92-49CC-84D8-E4E4DE1F023AQ27330218-6D60D4A9-9169-437C-93F8-3FA593064275Q27333771-4082684A-76AF-4D6C-9B4D-804432F536B4Q28205394-31E7F2BF-D060-446A-ACC3-4AF986EA0ABAQ28972559-E114F4B6-3CBB-49CE-9FCA-1F20318DC511Q30552405-5DA3C49B-B3E5-495F-A1C2-BDA2B1115C9BQ33918627-84D413E2-7E42-4339-A31F-6B71BE024A11Q34124035-21D12FA8-7E29-4FF8-BF98-F8D775D70AB4Q34276582-706629C4-38FA-4742-ACF5-2F77EEDA83C7Q34647574-06B8D246-91FA-418E-A267-19C6A8B92CA0Q35077681-AD07A3A4-F833-4657-9300-BB720964E94AQ35641009-7F2FBE65-2CC8-4300-8DFD-6921FF54005DQ35895566-29F222C0-0A90-42C4-BEE2-97D647CEAF26Q35980806-D160885E-53DB-4B3C-A21E-FF2C70B1F704Q36277182-4D1E1519-CCDC-4128-BE03-054C7AF62C2BQ36630985-D05059E2-53AB-483B-AB8F-0E04F9636D4BQ36747721-701B9D77-D755-48F7-A581-0C7356288208Q36955176-2D30C7EB-0AAA-40E1-9D33-41698F9760E9Q37019655-8A7A73AE-E047-43F4-99E5-B9E68F34F7C0Q37450453-15A71E8E-D259-4E43-8032-1D934927880EQ37800652-0FC3760C-9FE0-4A73-A9BE-49CA69EF3D24Q38090473-663315EB-D00C-462A-8641-BB2CE5AEA242Q38614523-50289950-9986-476D-8C8F-522C9359C7BEQ38636508-0BEA7912-D283-493A-9F9A-7CC50EF31F7CQ38636569-40E836F0-E50B-4259-8F3F-83CFB2AB4CEBQ38658382-E8DEB33D-5C15-4041-900E-6DA0EE934F38Q38825350-B61C4F91-CF67-4B87-86B1-E3831E1492DBQ39097992-CFB44A9A-5E7F-4A98-AE2C-1DE76134A27FQ39160992-E42CA5DA-0982-49BA-858E-BDA8CB1A7C1EQ40267812-6DA56B70-8517-4B8E-B352-6BB79C0B59CDQ42190071-545D8606-BD4F-494B-8DA3-619BE2A86D03Q42211170-560DCC5E-F8DF-41E1-A75D-72F3EC11FC65Q45760717-194E3485-48C6-4658-8460-E125A329F3B1Q47558073-DA62846F-156C-4557-ADC3-3A756BBC5930Q47970705-01CA183A-DAB2-4293-AB6B-B1C349CDD4EEQ48508304-D1E7101E-9185-4155-8FF4-A28F00247760Q54329285-561E1E3B-38B6-4A3D-919F-774DAE45B2DDQ57092554-92EDA89E-BA30-4F03-A3A1-F4B8C5E2CE47Q57472612-F033A2EA-060B-4A3B-8964-61E9FD1CBCCE
P2860
Immunofluorescence analysis of poliovirus receptor expression in Peyer's patches of humans, primates, and CD155 transgenic mice: implications for poliovirus infection.
description
2002 nî lūn-bûn
@nan
2002年の論文
@ja
2002年学术文章
@wuu
2002年学术文章
@zh
2002年学术文章
@zh-cn
2002年学术文章
@zh-hans
2002年学术文章
@zh-my
2002年学术文章
@zh-sg
2002年學術文章
@yue
2002年學術文章
@zh-hant
name
Immunofluorescence analysis of ...... ions for poliovirus infection.
@en
Immunofluorescence analysis of ...... ions for poliovirus infection.
@nl
type
label
Immunofluorescence analysis of ...... ions for poliovirus infection.
@en
Immunofluorescence analysis of ...... ions for poliovirus infection.
@nl
prefLabel
Immunofluorescence analysis of ...... ions for poliovirus infection.
@en
Immunofluorescence analysis of ...... ions for poliovirus infection.
@nl
P2093
P356
P1476
Immunofluorescence analysis of ...... ions for poliovirus infection.
@en
P2093
Akiko Iwasaki
Akio Nomoto
Melissa Linehan
Reinhold Welker
Steffen Mueller
P304
P356
10.1086/342682
P407
P577
2002-08-09T00:00:00Z