about
Mechanisms of change in gene copy numberSelfish genes, the phenotype paradigm and genome evolutionA highly conserved domain of the maize activator transposase is involved in dimerizationEvidence for the adaptive significance of an LTR retrotransposon sequence in a Drosophila heterochromatic geneTransposable Elements, Polydactyl Proteins, and the Genesis of Human-Specific Transcription NetworksMechanisms of stress in the brainSomatic mosaicism in the human genomeChromosome boundary elements and regulation of heterochromatin spreadingUntangling the web: the diverse functions of the PIWI/piRNA pathwayThe role of transposable elements in health and diseases of the central nervous systemGeneration of tandem direct duplications by reversed-ends transposition of maize ac elementsThe three-dimensional structure of a Tn5 transposase-related protein determined to 2.9-A resolutionMolecular epigenetic switches in neurodevelopment in health and diseaseAberrant Transpositions of Maize Double Ds-Like Elements Usually Involve Ds Ends on Sister ChromatidsEpi-alleles in plants: inheritance of epigenetic information over generationsThe taming of a transposon: V(D)J recombination and the immune systemEpigenetic variation in Arabidopsis disease resistancePlant MITEs: useful tools for plant genetics and genomicsMIR retrotransposon sequences provide insulators to the human genomeGREAM: A Web Server to Short-List Potentially Important Genomic Repeat Elements Based on Over-/Under-Representation in Specific Chromosomal Locations, Such as the Gene Neighborhoods, within or across 17 Mammalian SpeciesNuclear function of AlusDNA transposons and the evolution of eukaryotic genomesSmall RNAs as guardians of the genomeNovel folded protein domains generated by combinatorial shuffling of polypeptide segments.InsertionMapper: a pipeline tool for the identification of targeted sequences from multidimensional high throughput sequencing data.An integrative framework for the identification of double minute chromosomes using next generation sequencing data.Chromosomal locus rearrangements are a rapid response to formation of the allotetraploid Arabidopsis suecica genomeOn the mechanism of gene amplification induced under stress in Escherichia coliGlobal gene expression analysis of the shoot apical meristem of maize (Zea mays L.).A novel Snf2 protein maintains trans-generational regulatory states established by paramutation in maize.The maize LAG1-O mutant suggests that reproductive cell lineages show unique gene expression patterns early in vegetative development.Transcriptome analysis of a spontaneous mutant in sweet orange [Citrus sinensis (L.) Osbeck] during fruit development.Cloning Knotted, the dominant morphological mutant in maize using Ds2 as a transposon tag.Nuclear organization and chromosome segregation.Chromosomes, 11Q and cancer: a review.Transposable elements as a molecular evolutionary force.Burst expansion, distribution and diversification of MITEs in the silkworm genomeEffects of Temperature on Spontaneous and Induced Mutations in Escherichia ColiA Factor (or Mutator Gene) Influencing Mutation Rates in Escherichia ColiThe Relation between Modulator and Activator in Maize
P2860
Q22122003-0CA8B98C-7C8D-4A00-BD29-42EDE75E67FEQ22122418-0914BDD4-0760-4046-ABE1-A6EE4F3CB170Q24540071-604299FF-4176-462D-9BD1-4DCB8DE48290Q24806427-3C35CAAF-B74D-4A0C-8582-FF1AB37C8AB6Q26772090-2E8BA636-8F67-4FA7-8638-022DF6723897Q26781233-CB25A377-0BC7-44AF-A0DD-DB82FF2172FFQ26823199-102BE62D-6BF0-40FE-A460-B942B25E55FDQ26827448-21FF506C-6135-417C-97FC-D4D745019168Q26851359-C62E09D0-6340-461A-A466-75B5DC1E78A3Q27022344-D2CEB274-756E-42A3-BAA8-7C63C5527DE6Q27320841-41DC2145-0E1A-4158-901B-586CDEB59F66Q27617962-699BC6EF-89F0-4995-97F7-05919892165EQ28083013-F1DB4CE9-6916-4327-8A3C-F033A644C879Q28202801-45952BBA-185E-4607-A882-AE5EFA0D9B5EQ28212227-CFE80758-1DC1-4F45-B040-5076CB506A14Q28270945-8441A283-7D02-4D68-AAC8-8F18238B0687Q28345294-C31F0EEC-0780-47B8-9983-A6912E523E83Q28585716-5C517F7F-F4AD-4B1A-A2FB-06AA5BD80AA4Q28610752-6F59CFE0-45A0-4E26-802B-68445DE2712FQ28646510-21EACAE7-B412-462D-BAA1-70BC2A55B218Q28658599-079504A8-9C53-49F1-8693-601B27D618EDQ29617153-8A4D1B4F-9372-4AB4-A18A-E20A1C3C6E5DQ29617221-55152045-F010-4C27-9274-F580D241FF9EQ30168811-B234DAD7-C9B0-4794-A1E6-89AAB22960CEQ30671229-4486BEAD-373A-449B-A724-D0542D2C7075Q30946533-742E3104-6839-4909-8D4D-D5D3CED7771EQ30978658-7CF72219-D3E1-4189-AA3B-E006F3E343DBQ33239373-1E6F713E-98E7-4033-A6F8-7749714FC39EQ33296298-A0027B6B-840E-4287-BA6F-A03409215678Q33302945-320CCF28-83E7-4910-B8F4-041E257A8E2DQ33335249-626CA721-4FA9-49DB-B0D6-BA0B69D52DF9Q33409336-08467077-DFD6-403D-9678-31E37E5D07D3Q33557220-16F78390-4D4D-470A-90D9-778A9A279867Q33600182-7277E181-1680-4C0C-ACF9-17E98B0D2F55Q33643315-840926CD-7DCF-41F7-BBE8-77D043C5D1A4Q33692323-37165861-8604-4D3A-8C88-FEAC7CD41461Q33704503-F6FECC00-D9D7-4292-B914-2A267988FAB7Q33713533-72113C57-0D41-4F9A-9903-C5E54FBFF211Q33714309-F835B04C-561D-4F45-AAA2-1D7FAA5D16B4Q33714373-6FF7C2F6-4A7C-42CB-8281-8FE6ABDDC0F4
P2860
description
1951 nî lūn-bûn
@nan
1951 թուականին հրատարակուած գիտական յօդուած
@hyw
1951 թվականին հրատարակված գիտական հոդված
@hy
1951年の論文
@ja
1951年論文
@yue
1951年論文
@zh-hant
1951年論文
@zh-hk
1951年論文
@zh-mo
1951年論文
@zh-tw
1951年论文
@wuu
name
Chromosome organization and genic expression
@ast
Chromosome organization and genic expression
@en
Chromosome organization and genic expression
@nl
type
label
Chromosome organization and genic expression
@ast
Chromosome organization and genic expression
@en
Chromosome organization and genic expression
@nl
prefLabel
Chromosome organization and genic expression
@ast
Chromosome organization and genic expression
@en
Chromosome organization and genic expression
@nl
P3181
P1476
Chromosome organization and genic expression
@en
P3181
P356
10.1101/SQB.1951.016.01.004
P407
P577
1951-01-01T00:00:00Z