Virus adaptation by manipulation of host's gene expression.
about
Role of genomic and proteomic tools in the study of host-virus interactions and virus evolutionExperimental evolution of an emerging plant virus in host genotypes that differ in their susceptibility to infection.Simultaneous mutations in multi-viral proteins are required for soybean mosaic virus to gain virulence on soybean genotypes carrying different R genes.Comparative analysis of microarray data in Arabidopsis transcriptome during compatible interactions with plant viruses.A meta-analysis reveals the commonalities and differences in Arabidopsis thaliana response to different viral pathogensTranscriptional analysis of South African cassava mosaic virus-infected susceptible and tolerant landraces of cassava highlights differences in resistance, basal defense and cell wall associated genes during infection.Relationship between symptoms and gene expression induced by the infection of three strains of Rice dwarf virusAssessing Global Transcriptome Changes in Response to South African Cassava Mosaic Virus [ZA-99] Infection in Susceptible Arabidopsis thalianaIntra-specific variability and biological relevance of P3N-PIPO protein length in potyvirusesTranscription, translation, and the evolution of specialists and generalists.Ecological and genetic determinants of Pepino Mosaic Virus emergenceShrinkage of genome size in a plant RNA virus upon transfer of an essential viral gene into the host genomeEvolutionary transitions during RNA virus experimental evolution.Effect of host species on the topography of fitness landscape for a plant RNA virus.The transcriptomics of an experimentally evolved plant-virus interaction.Interaction network of tobacco etch potyvirus NIa protein with the host proteome during infectionAdaptation of tobacco etch potyvirus to a susceptible ecotype of Arabidopsis thaliana capacitates it for systemic infection of resistant ecotypes.The impact of high-order epistasis in the within-host fitness of a positive-sense plant RNA virus.Evaluating the within-host fitness effects of mutations fixed during virus adaptation to different ecotypes of a new hostComputational design of host transcription-factors sets whose misregulation mimics the transcriptomic effect of viral infectionsTranscript Profiling of Different Arabidopsis thaliana Ecotypes in Response to Tobacco etch potyvirus Infection.Amino acid changes in P3, and not the overlapping pipo-encoded protein, determine virulence of soybean mosaic virus on functionally immune Rsv1-genotype soybean.Differential tomato transcriptomic responses induced by pepino mosaic virus isolates with differential aggressiveness.Co-evolution between Grapevine rupestris stem pitting-associated virus and Vitis vinifera L. leads to decreased defence responses and increased transcription of genes related to photosynthesis.Dose-dependent effects of an immune challenge at both ultimate and proximate levels in Drosophila melanogaster.Viral fitness correlates with the magnitude and direction of the perturbation induced in the host's transcriptome: the tobacco etch potyvirus - tobacco case study.Efficient escape from local optima in a highly rugged fitness landscape by evolving RNA virus populations.Viral Determinants and Vector Competence of Zika Virus Transmission.The effects of a bacterial challenge on reproductive success of fruit flies evolved under low or high sexual selection
P2860
Q28661548-98059C57-C093-4963-A363-5CBC8D1D1F5CQ31162373-275E137C-9997-4F01-815D-3486B44B9E29Q34091487-68201B0A-A6EE-4868-B9C1-85C3996ED73AQ34285431-054826AD-35D9-40DF-A28B-C1CDF76646ADQ34342104-26404324-CB3B-48C4-B6AD-A9BA6241C2FDQ34617209-660D4B4D-CCA9-4592-AFFF-D8278124CBD1Q34708348-26E70862-8928-4B3B-89A8-5CCAE78C6974Q34797355-42B6C98F-52A4-4A4C-898F-44497851A267Q35041856-5AD4FA9C-5722-4D2E-8647-CA0FE26E9720Q37434387-ED9F54C4-55E3-4774-ADFA-868248C8845FQ37643729-8669259E-CFED-4B07-B7E8-17A2ABA4130FQ38578331-A2317CE2-65CB-4746-B62D-6B5421765181Q38901565-1BFB316F-B05E-457D-AB31-5D9A7A9DF97AQ40599352-F0D2E909-B143-4B7B-A1D4-0AD9DE1A9D29Q40626916-A6C903F7-8202-44E7-8420-D7055C52851EQ40810687-209884BE-3462-4706-BA96-2B33B4BAA227Q40863118-AD5D6544-8CB0-4FE9-A477-283832A0FDC0Q41012991-A5709EE3-929B-4DE6-A18A-A08028995CB3Q41119821-43CD2E6D-ECD0-49C6-8D6D-9515C3A40403Q41838244-B89B285C-612B-44AA-A87B-53A67917C020Q41912583-ED03CF0E-FABE-4C27-B2B2-4A266BEC3BE6Q42607654-57E45001-AFDE-4FE5-90B2-D940290A0CFFQ45227410-58F8D71B-A22B-457E-B991-DF5A99D4792BQ45354725-7F9E3F59-969B-40A2-9E19-E92C914B845EQ51146560-E6E9C9D8-742A-42DB-BB7E-F00A1C4FB95CQ52347585-E43E91E8-D6FA-460F-BEEB-0EA96A249C99Q53144970-F61FCA04-2A8A-40E3-BFAD-66B47ED7DE49Q55084391-CAE36AB0-F538-46EB-8E4B-88BF2B5B0E65Q58129555-F8E7B5D0-C498-4A32-B8CD-6B731A754709
P2860
Virus adaptation by manipulation of host's gene expression.
description
2008 nî lūn-bûn
@nan
2008 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
Virus adaptation by manipulation of host's gene expression.
@ast
Virus adaptation by manipulation of host's gene expression.
@en
type
label
Virus adaptation by manipulation of host's gene expression.
@ast
Virus adaptation by manipulation of host's gene expression.
@en
prefLabel
Virus adaptation by manipulation of host's gene expression.
@ast
Virus adaptation by manipulation of host's gene expression.
@en
P2860
P50
P1433
P1476
Virus adaptation by manipulation of host's gene expression.
@en
P2093
Miguel A Perez-Amador
P2860
P356
10.1371/JOURNAL.PONE.0002397
P407
P577
2008-06-11T00:00:00Z