Alu repeated DNAs are differentially methylated in primate germ cells
about
Epigenetic regulation of human embryonic stem cellsGenomic imprinting in mammals: emerging themes and established theoriesThe impact of retrotransposons on human genome evolutionWidespread A-to-I RNA editing of Alu-containing mRNAs in the human transcriptomeA Mouse Model for Imprinting of the Human Retinoblastoma GeneDo repeated arrays of regulatory small-RNA genes elicit genomic imprinting?: Concurrent emergence of large clusters of small non-coding RNAs and genomic imprinting at four evolutionarily distinct eutherian chromosomal lociLINEs, SINEs and other retroelements: do birds of a feather flock together?Analysis of tissue-specific differentially methylated regions (TDMs) in humansEvidence of influence of genomic DNA sequence on human X chromosome inactivationA screen for retrotransposed imprinted genes reveals an association between X chromosome homology and maternal germ-line methylationGenome-wide profiling of DNA methylation reveals a class of normally methylated CpG island promoters.Methylation status of individual CpG sites within Alu elements in the human genome and Alu hypomethylation in gastric carcinomas.Evolution and functional classification of vertebrate gene deserts.K562 cells implicate increased chromatin accessibility in Alu transcriptional activation.The (r)evolution of SINE versus LINE distributions in primate genomes: sex chromosomes are important.Short interspersed transposable elements (SINEs) are excluded from imprinted regions in the human genome.Bidirectional promoters as important drivers for the emergence of species-specific transcripts.Does SINE evolution preclude Alu function?Determinants of CpG islands: expression in early embryo and isochore structureThe origin of the RB1 imprint.Chromosome methylation patterns during mammalian preimplantation developmentHuman piRNAs are under selection in Africans and repress transposable elements.Analysis of deletion breakpoints from 1,092 humans reveals details of mutation mechanisms.Causes and consequences of DNA hypomethylation in human cancer.Allele-specific demethylation at an imprinted mammalian promoterDistribution of a marker of germline methylation differs between major families of transposon-derived repeats in the human genome.Whole-genome bisulfite sequencing maps from multiple human tissues reveal novel CpG islands associated with tissue-specific regulationDNA methylation variation of human-specific Alu repeatsEpigenetics: differential DNA methylation in mammalian somatic tissues.Obesity-induced sperm DNA methylation changes at satellite repeats are reprogrammed in rat offspring.Functional microRNAs and target sites are created by lineage-specific transposition.Origin and evolution of SINEs in eukaryotic genomes.Transposable element recruitments in the mammalian placenta: impacts and mechanisms.Transgenerational epigenetic inheritance: adaptation through the germline epigenome?Epigenetic nucleosomes: Alu sequences and CG as nucleosome positioning element.A pseudoautosomal boundary-like element adjacent to the SSAV1 locus at 18q21.Cytosine deamination plays a primary role in the evolution of mammalian isochores.Specific Alu binding protein from human sperm chromatin prevents DNA methylation.
P2860
Q21131246-EE511BA3-EB40-4A23-A1D6-873A01B523CFQ21145256-EDD5FF4E-D9AF-4DD6-9C68-8F61A81235EFQ24594901-0DB9C01C-A270-4E85-AF0E-E65A07CA5DAAQ24806860-CAD82C1F-B45A-4FD2-82B7-77E9254E8E47Q27301081-2FBD0DC9-313C-4075-819E-4FCF4FD13DA9Q28238792-905C7FDC-360D-4B83-8723-5F877FD86596Q28729045-8895D971-DD0A-4351-9A05-8ACAA613E405Q28762983-971F252F-1587-4103-8BB2-5E0973A3E191Q33256101-FD01E3B8-766B-4E90-8291-9E3B7646F966Q33273037-72897E36-ACE9-4F9F-904B-B27237CF5BC3Q33304220-60304CF0-5A66-4620-BB1C-30E9E5A2E88CQ33531949-A0422D80-C8C7-414E-AF32-03C2D7C58EE4Q33596085-E14CBBE3-EA1C-4A41-AD4B-1A3ADCA70B67Q33758372-986C05EE-62EA-4650-8CB9-C059E8659EF2Q33812545-AA0261B4-32DE-4234-B4FB-E98FD00A61AEQ33897588-93952DEC-1776-4DD2-9819-73CB390CC4D7Q34608484-9FF3E01E-6711-43D8-9DAB-0D355309616BQ34679535-61947D65-AD22-489C-8EC9-B2B2FA3DDE6EQ35036078-8D271B8F-0822-4BDC-87CC-7AF645626B2CQ35055331-FEEE2C7D-F907-4C99-8478-AEB33257C564Q35205639-5D33B1FF-79E5-4AB7-A412-FB4D8B6E3A47Q35422999-51DC9DFE-33CE-44E6-9317-2D8450EA71E8Q35672565-FBB6E205-7C7D-4B16-B686-1AAEB52219BAQ36164751-2CBADA7A-6835-4BB8-A31A-221A4774F396Q36328828-BC8D0F55-0905-41AA-97F9-84DDC4090FDCQ36331117-5372D9A3-126F-4407-9715-937A68A48092Q36402568-C10DCDDB-8EE6-4E0C-ADAC-FD5B0C147E90Q36838942-96992B3C-1638-467A-8E89-54D6AC5BC226Q37106583-6F45D0DA-FCF2-4B59-8EF7-C2EBE34CE94FQ37414998-ADEB193F-E25F-47E0-B8C8-EF5B70211A42Q37619287-2E71786A-37FD-418B-A2AB-197E5CE743CAQ37889635-A6173E21-1D7E-419D-AE93-201964A0EDD4Q38023371-89052303-3909-4E1D-A256-6CF52F394EAEQ38586384-F532A879-141F-41D0-81E0-62DC931A7E3CQ43971420-41E67E8F-DFC7-450E-B9A7-8AEAAB443E1BQ44080867-315557EB-456D-4014-BA7A-15A033DC4D3DQ44875348-F6A56362-A71E-4B65-8B25-916AB3915F3BQ46112192-E4102771-5796-46FA-A3AC-17C9E9A00540
P2860
Alu repeated DNAs are differentially methylated in primate germ cells
description
1994 nî lūn-bûn
@nan
1994年の論文
@ja
1994年学术文章
@wuu
1994年学术文章
@zh-cn
1994年学术文章
@zh-hans
1994年学术文章
@zh-my
1994年学术文章
@zh-sg
1994年學術文章
@yue
1994年學術文章
@zh
1994年學術文章
@zh-hant
name
Alu repeated DNAs are differentially methylated in primate germ cells
@en
Alu repeated DNAs are differentially methylated in primate germ cells.
@nl
type
label
Alu repeated DNAs are differentially methylated in primate germ cells
@en
Alu repeated DNAs are differentially methylated in primate germ cells.
@nl
prefLabel
Alu repeated DNAs are differentially methylated in primate germ cells
@en
Alu repeated DNAs are differentially methylated in primate germ cells.
@nl
P2093
P2860
P356
P1476
Alu repeated DNAs are differentially methylated in primate germ cells
@en
P2093
C A VandeVoort
C W Schmid
R L Teplitz
P2860
P304
P356
10.1093/NAR/22.23.5121
P407
P577
1994-11-01T00:00:00Z