Comparison of two aquatic alphaviruses, salmon pancreas disease virus and sleeping disease virus, by using genome sequence analysis, monoclonal reactivity, and cross-infection.
about
Discovery of frameshifting in Alphavirus 6K resolves a 20-year enigmaBiological Transmission of Arboviruses: Reexamination of and New Insights into Components, Mechanisms, and Unique Traits as Well as Their Evolutionary TrendsRainbow trout (Oncorhynchus mykiss) muscle satellite cells are targets of salmonid alphavirus infectionReal-time whole-body visualization of Chikungunya Virus infection and host interferon response in zebrafishA Phylogenomic Study of the Genus Alphavirus Employing Whole Genome ComparisonA structural and functional perspective of alphavirus replication and assemblyGenome-scale phylogeny of the alphavirus genus suggests a marine originEilat virus, a unique alphavirus with host range restricted to insects by RNA replicationDevelopment of infectious cDNA clones of Salmonid alphavirus subtype 3.Molecular epidemiology of salmonid alphavirus (SAV) subtype 3 in Norway.Functional analysis of nsP3 phosphoprotein mutants of Sindbis virus.Recovery of a recombinant salmonid alphavirus fully attenuated and protective for rainbow trout.The reverse genetics applied to fish RNA viruses.The contribution of molecular epidemiology to the understanding and control of viral diseases of salmonid aquaculture.Chikungunya virus 3' untranslated region: adaptation to mosquitoes and a population bottleneck as major evolutionary forces.The serum proteome of Atlantic salmon, Salmo salar, during pancreas disease (PD) following infection with salmonid alphavirus subtype 3 (SAV3)De novo assembly and transcriptome analysis of Atlantic salmon macrophage/dendritic-like TO cells following type I IFN treatment and Salmonid alphavirus subtype-3 infection.A 6K-deletion variant of salmonid alphavirus is non-viable but can be rescued through RNA recombination.Alphavirus infections in salmonids--a review.Relationship between viral dose and outcome of infection in Atlantic salmon, Salmo salar L., post-smolts bath-challenged with salmonid alphavirus subtype 3.Experimental piscine alphavirus RNA recombination in vivo yields both viable virus and defective viral RNA.RNA viruses in the sea.Viruses of fish: an overview of significant pathogens.Disentangling the Frames, the State of Research on the Alphavirus 6K and TF Proteins.A historical review of the key bacterial and viral pathogens of Scottish wild fish.A Viral mRNA Motif at the 3'-Untranslated Region that Confers Translatability in a Cell-Specific Manner. Implications for Virus Evolution.Comparison of complete polyprotein sequences of two isolates of salmon alphavirus (SAV) type I and their behaviour in a salmonid cell line.Ultrastructural morphogenesis of salmonid alphavirus 1.Alpha interferon and not gamma interferon inhibits salmonid alphavirus subtype 3 replication in vitroA fully attenuated recombinant Salmonid alphavirus becomes pathogenic through a single amino acid change in the E2 glycoproteinVaccination against pancreas disease in Atlantic salmon, Salmo salar L., reduces shedding of salmonid alphavirus.A rapid immunoperoxidase-based virus neutralization assay for salmonid alphavirus used for a serological survey in Northern Ireland.Pathogenesis of experimental salmonid alphavirus infection in vivo: an ultrastructural insightGenetic characterization of salmonid alphavirus in Norway.Characterization of untranslated regions of the salmonid alphavirus 3 (SAV3) genome and construction of a SAV3 based replicon.Cross-sectional study to investigate the presence of salmon pancreas disease virus in wild and feral fish populations in 10 lakes, Los Lagos Region, Chile.Cross-neutralization studies with salmonid alphavirus subtype 1-6 strains: results with sera from experimental studies and natural infections.No influence of oxygen levels on pathogenesis and virus shedding in Salmonid alphavirus (SAV)-challenged Atlantic salmon (Salmo salar L.).Geographical distribution of salmonid alphavirus subtypes in marine farmed Atlantic salmon, Salmo salar L., in Scotland and Ireland.Regulation of the sequential processing of Semliki Forest virus replicase polyprotein.
P2860
Q21245130-1D97CF4C-639A-4E9B-B286-D635A754C030Q24289112-66FCF430-7615-4A69-9918-F1CAB1DF9ACDQ24701728-50493A26-4C61-4BD4-9533-7B0B8B837BCAQ27333104-98F479A8-C240-4967-8871-CAA9DE2EF2B0Q27486414-8EC758A5-70BA-454D-840E-50BFC8B9B788Q27490173-36D6E8F9-1CA3-49C3-AD43-1C23B2E4CA84Q28255956-0ADE0738-737F-4565-BB5A-9EBBCBD9232EQ28954701-488382DF-DF2E-4D40-826D-FD0A30469FB6Q33698552-A7195554-721E-4964-8903-AC51625A74A0Q34078372-6752B03A-5127-4A2D-97B7-5D0A3D21C863Q34227437-F4958B20-3A82-4F25-BEF3-805135E7D5E8Q34545897-C9422F81-4C82-495C-80C2-BFB663F24FA6Q34569574-1CF63EAC-F037-4E15-8C1A-3BB6BF11296EQ34832642-B37FD5ED-E8D0-4A4C-8F17-733AC77CA414Q34979371-3B4B5A7B-98E1-46B6-9CD9-EABF7CA17B3AQ35022017-847F785B-5885-4077-9A1C-40E7E3092261Q35109562-E2D3E8A2-2256-4D22-9F3C-73002482EDBAQ35204260-59E9A8D4-7E29-483E-8705-C43FE43868B7Q36918919-1D92C951-CCA1-4A81-804F-76A6A9639C2DQ37349703-006C1338-C53F-499F-9DAA-64D9A74AD63EQ37387332-AE24CF20-33F0-45F3-9AC5-3F9B2E34DD64Q37401404-F178D30A-1D95-43D4-ABAC-4827A237C22FQ37967730-E493D986-F3BB-4FBE-BE6D-3882F71E41BFQ38618537-106E0276-A7E4-46E5-A3F3-B9081AC3B73DQ38674076-2FE22BC8-14CC-466D-B437-3F9CB8CD1B12Q38804679-0F7F9760-7722-4767-9B84-F5F95E3187DEQ39164477-69661E1E-951D-401A-91A9-AF58B02D4806Q39293003-92374ECD-09CA-44B1-9DFD-2B71CD8CF900Q39688962-CAE5311C-8DFA-4993-862F-F62BB3FAF8B7Q40529602-B6DF4152-2F58-4BE8-BC14-EE87DE621603Q40586515-CFBE192E-120A-4A39-AA1C-4BABA384BB94Q40639450-CAD07673-9B1A-4956-979A-98B534BDD127Q40840984-196957D6-2260-46D8-805E-0BF9C740CC49Q41482429-F3893E96-AFAD-46B3-8E21-0971F02AB6A0Q42119380-F6B248AF-AC12-435E-8419-2ACBA4081926Q42245827-B3A6838C-C0A3-4ED8-B9FF-04D99D051A82Q42275740-176F0AC7-68A1-42A0-97AC-D8366F843834Q42429091-987EAA2E-E59A-4B54-954C-DEC10492B313Q43869173-9AA35917-2F1A-42EF-AF32-7CC4CFF9C544Q44548826-7C534336-106D-4158-AEFA-7278EA2E2DF1
P2860
Comparison of two aquatic alphaviruses, salmon pancreas disease virus and sleeping disease virus, by using genome sequence analysis, monoclonal reactivity, and cross-infection.
description
2002 nî lūn-bûn
@nan
2002 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Comparison of two aquatic alph ...... activity, and cross-infection.
@ast
Comparison of two aquatic alph ...... activity, and cross-infection.
@en
Comparison of two aquatic alph ...... activity, and cross-infection.
@nl
type
label
Comparison of two aquatic alph ...... activity, and cross-infection.
@ast
Comparison of two aquatic alph ...... activity, and cross-infection.
@en
Comparison of two aquatic alph ...... activity, and cross-infection.
@nl
prefLabel
Comparison of two aquatic alph ...... activity, and cross-infection.
@ast
Comparison of two aquatic alph ...... activity, and cross-infection.
@en
Comparison of two aquatic alph ...... activity, and cross-infection.
@nl
P2093
P2860
P1433
P1476
Comparison of two aquatic alph ...... activity, and cross-infection.
@en
P2093
Daniel Todd
Jeanette Castric
Jonathan Weston
Joseph Koumans
Karen Elina Christie
Marian McLoughlin
Martin Pfeffer
Michel Brémont
OddMagne Rødseth
Stéphane Villoing
P2860
P304
P356
10.1128/JVI.76.12.6155-6163.2002
P407
P577
2002-06-01T00:00:00Z