Transposed genes in Arabidopsis are often associated with flanking repeats
about
The Arabidopsis lyrata genome sequence and the basis of rapid genome size changeLineage-specific conserved noncoding sequences of plant genomes: their possible role in nucleosome positioningComputational analysis and characterization of UCE-like elements (ULEs) in plant genomesNatural insertions in rice commonly form tandem duplications indicative of patch-mediated double-strand break induction and repair.Evolutionary divergence and limits of conserved non-coding sequence detection in plant genomes.Modes of gene duplication contribute differently to genetic novelty and redundancy, but show parallels across divergent angiosperms.Formation of plant metabolic gene clusters within dynamic chromosomal regions.Whole-genome sequencing of Oryza brachyantha reveals mechanisms underlying Oryza genome evolution.Genomic rearrangements and the evolution of clusters of locally adaptive loci.Genome-wide expression analysis of soybean MADS genes showing potential function in the seed development.MicroRNA regulation of plant innate immune receptors.The impact and origin of copy number variations in the Oryza speciesLarge-Scale Gene Relocations following an Ancient Genome Triplication Associated with the Diversification of Core EudicotsGenome-wide survey and comprehensive expression profiling of Aux/IAA gene family in chickpea and soybean.SynFind: Compiling Syntenic Regions across Any Set of Genomes on DemandStructure, organization and evolution of ADP-ribosylation factors in rice and foxtail millet, and their expression in riceThe pineapple genome and the evolution of CAM photosynthesisRepair of adjacent single-strand breaks is often accompanied by the formation of tandem sequence duplications in plant genomes.The evolution of the plastid chromosome in land plants: gene content, gene order, gene functionEvolutionary and comparative analysis of MYB and bHLH plant transcription factors.Genome and gene duplications and gene expression divergence: a view from plants.How important are transposons for plant evolution?Contrasting patterns of evolution following whole genome versus tandem duplication events in Populus.Shared subgenome dominance following polyploidization explains grass genome evolutionary plasticity from a seven protochromosome ancestor with 16K protogenes.Unconventional circularizable bacterial genetic structures carrying antibiotic resistance determinants.Different gene families in Arabidopsis thaliana transposed in different epochs and at different frequencies throughout the rosids.Gene body methylation shows distinct patterns associated with different gene origins and duplication modes and has a heterogeneous relationship with gene expression inOryza sativa(rice)Factors Influencing Gene Family Size Variation Among Related Species in a Plant Family, Solanaceae
P2860
Q22122056-1FDE6487-18CA-4ECC-8EF0-3F61C0DE8474Q28654571-0A6F0841-4D0A-40C7-803D-2F585600BE30Q28710416-70631F0E-12BF-4752-9E2A-3A3B2F90CE6EQ33606989-C8DBF68D-DA85-4E67-A781-BC5433843D1FQ33864398-709E988C-61A1-44CC-AAA0-214DB8C66274Q34099016-EBD998D5-C02F-4638-9353-FCFD9EA3A72BQ34211703-E7FA9492-9D04-4670-B3FB-60A001B2EF75Q34332386-C3CF8A44-EEAD-4F04-886E-19D76532E837Q34682169-62ED668E-4661-49F8-99FE-4DC63E95558AQ34701176-B925191B-2A90-4985-A5B0-D94D8F243A12Q35749567-8C21C1EA-B331-4852-B7F7-FD3027894DD4Q35973139-62D4A4BA-5862-40EE-9BB7-E581103DB9BBQ36022356-35591856-5DED-4E43-8BE0-75BC9C6FC1E5Q36210427-D80D3FF9-7ADA-49FB-9A94-291229543A83Q36429472-A970B6E8-19AB-4E0F-9349-12FEF685043CQ36819699-08E29777-C78A-44E0-B89E-6D0A8D6BBEF4Q36901868-DE70FF3E-3921-4674-9BD4-0536FD18225BQ37065222-AE444FC3-61D1-4FD7-ACC7-2B7EDCB17D1FQ37855690-8CEF6E67-BB04-441E-B493-94B5D83B3F62Q37858622-2708ECB4-45FD-422A-8A74-F91C48308D35Q37976849-46D64B14-C24E-4AA4-946D-88973DB9CCFDQ38068090-6410FCE6-AB89-4702-A5D1-8C0DED6408A9Q39996455-5311B4C8-336B-4BDA-9687-0B8758451FABQ41916735-0522F327-834A-44B8-BA7D-BE3D7FB63217Q43188095-2725E7A1-61E2-492A-A8D7-7BF98784C8C3Q46009006-68175F59-E62D-4946-8486-CA43081FB3E3Q57721485-91072580-DEB5-4704-841E-09574B86FC93Q58721935-4C76ED2F-4BEC-4678-828A-1C1DDD99FF8E
P2860
Transposed genes in Arabidopsis are often associated with flanking repeats
description
2010 nî lūn-bûn
@nan
2010 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
name
Transposed genes in Arabidopsis are often associated with flanking repeats
@ast
Transposed genes in Arabidopsis are often associated with flanking repeats
@en
Transposed genes in Arabidopsis are often associated with flanking repeats
@nl
type
label
Transposed genes in Arabidopsis are often associated with flanking repeats
@ast
Transposed genes in Arabidopsis are often associated with flanking repeats
@en
Transposed genes in Arabidopsis are often associated with flanking repeats
@nl
prefLabel
Transposed genes in Arabidopsis are often associated with flanking repeats
@ast
Transposed genes in Arabidopsis are often associated with flanking repeats
@en
Transposed genes in Arabidopsis are often associated with flanking repeats
@nl
P2860
P3181
P1433
P1476
Transposed genes in Arabidopsis are often associated with flanking repeats
@en
P2093
Brent Pedersen
Margaret R Woodhouse
P2860
P304
P3181
P356
10.1371/JOURNAL.PGEN.1000949
P407
P577
2010-05-01T00:00:00Z