about
Human amiloride-sensitive epithelial Na+ channel gamma subunit promoter: functional analysis and identification of a polypurine-polypyrimidine tract with the potential for triplex DNA formationInactivation of CMP-N-acetylneuraminic acid hydroxylase occurred prior to brain expansion during human evolutionSINE insertions in cladistic analyses and the phylogenetic affiliations of Tarsius bancanus to other primatesAlu-mediated inactivation of the human CMP- N-acetylneuraminic acid hydroxylase geneAlu elements and hominid phylogeneticsComparative genomics and molecular dynamics of DNA repeats in eukaryotesWhole-genome screening indicates a possible burst of formation of processed pseudogenes and Alu repeats by particular L1 subfamilies in ancestral primatesAnalysis of the human Alu Ye lineageThe association of Alu repeats with the generation of potential AU-rich elements (ARE) at 3' untranslated regionsExonization of AluYa5 in the human ACE gene requires mutations in both 3' and 5' splice sites and is facilitated by a conserved splicing enhancer.Tracking Alu evolution in New World primates.Sequencing of 42kb of the APO E-C2 gene cluster reveals a new gene: PEREC1Detection of differential DNA methylation in repetitive DNA of mice and humans perinatally exposed to bisphenol AAssociation of new deletion/duplication region at chromosome 1p21 with intellectual disability, severe speech deficit and autism spectrum disorder-like behavior: an all-in approach to solving the DPYD enigmaEnrichment analysis of Alu elements with different spatial chromatin proximity in the human genomeLINEs and SINEs of primate evolutionAnalysis of western lowland gorilla (Gorilla gorilla gorilla) specific Alu repeatsA novel endogenous betaretrovirus group characterized from polar bears (Ursus maritimus) and giant pandas (Ailuropoda melanoleuca)A divergent P element and its associated MITE, BuT5, generate chromosomal inversions and are widespread within the Drosophila repleta species groupA novel web-based TinT application and the chronology of the Primate Alu retroposon activityPeriodic explosive expansion of human retroelements associated with the evolution of the hominoid primateComprehensive analysis of the pseudogenes of glycolytic enzymes in vertebrates: the anomalously high number of GAPDH pseudogenes highlights a recent burst of retrotrans-positional activityEvolutionary history of mammalian transposons determined by genome-wide defragmentationThe evolutionary history of human DNA transposons: evidence for intense activity in the primate lineageAlu-mediated 100-kb deletion in the primate genome: the loss of the agouti signaling protein gene in the lesser apesDrosophila euchromatic LTR retrotransposons are much younger than the host species in which they resideCloning and analysis of the gene encoding the human neonatal Fc receptor.Novel PAX6 binding sites in the human genome and the role of repetitive elements in the evolution of gene regulation.Alu repeats increase local recombination rates.SNP profile within the human major histocompatibility complex reveals an extreme and interrupted level of nucleotide diversity.Dasheng and RIRE2. A nonautonomous long terminal repeat element and its putative autonomous partner in the rice genome.Molecular characterization and chromosomal distribution of Galileo, Kepler and Newton, three foldback transposable elements of the Drosophila buzzatii species complex.New insights into the genetic history of Tunisians: data from Alu insertion and apolipoprotein E gene polymorphisms.Alu elements contain many binding sites for transcription factors and may play a role in regulation of developmental processes.Widespread Alu repeat-driven expansion of consensus DR2 retinoic acid response elements during primate evolutionLTR retrotransposons in rice (Oryza sativa, L.): recent burst amplifications followed by rapid DNA loss.Evidence of Alu and B1 expression in dbEST.A physical map of human Alu repeats cleavage by restriction endonucleases.Transcriptome-wide Investigation of mRNA/circRNA in miR-184 and Its r.57c > u Mutant Type Treatment of Human Lens Epithelial Cells.Retrotransposons and their recognition of pol II promoters: a comprehensive survey of the transposable elements from the complete genome sequence of Schizosaccharomyces pombe.
P2860
Q24532005-0DD97E39-CDCC-4FDD-A823-BE9AF5262EF1Q24535641-B2AF0318-1A47-421E-BC99-02DA2F423AFCQ24548178-CD81B188-913F-4038-BD4D-DB62DCFCEF86Q24555185-0A2B3F55-24D7-4FC6-A2C6-750A327478BDQ24647435-6F9DFD8A-EA81-4176-8FB0-288AC784F2E2Q24650948-3DA14B02-533F-40B4-A114-9448FC0FB7F8Q24793332-92991A11-C0D1-4977-9FD7-7128101523C4Q24801027-DB46828F-1495-45E4-9434-E0F947B855D8Q24802486-E938C345-01C4-4345-9B72-725A2049A898Q24811113-10518CE4-BA09-4911-B997-FE51B917D8C9Q24816499-769DAFDC-ABCF-4A3D-9735-BA4A973E77C2Q28145847-F377EF2F-EECA-4F36-ADDE-4A7CC4E96774Q28596491-DC09C621-E597-4D68-89D2-AB5F463E7D1FQ28596636-F2C0DD78-F560-440A-9FF5-5763233DF5F3Q28601408-ADA5F599-33EE-4E8D-ABC5-F873E2C56BC2Q28654440-CAA4A6DB-D37C-4D0B-BD02-1728A9DD7690Q28655381-0A9DE7D1-18AB-427A-9CB6-111F36327AD6Q28680704-10F14EAC-18D1-4170-A73C-17ABE631766EQ28680731-A83320E5-12A3-4B35-B47C-D071712CA2BDQ28743726-20A4863F-94B1-45D5-95A0-D97C7B0B1FDCQ28748879-69CCCC0E-0213-4AE5-829A-5DDB10E00EFFQ28750314-3A79E9CF-316B-4DEB-9D97-0AC68526060BQ28757412-FCD29674-9F15-4494-8FEA-ED80B476C57DQ28763139-F5536621-41F7-4FD2-A103-C5488A2FB241Q28768074-96134308-A10D-45EA-A3F1-A65DE04F8043Q28776436-5A9BE313-64D3-41E4-9FD1-33FB9D929176Q30656411-142BAD48-3B73-47D5-B495-CB442FF0AB4EQ30868849-E0FA737F-AE2A-45F0-9737-83F0AF96FF88Q30886835-BBB611D3-25C0-4B33-9DFD-04920735CE8CQ30947228-124ACBF8-0DA5-4CBE-85E8-25FE5F7204F8Q31121410-4D039D74-3221-453F-AD5B-89E049F63A11Q31146608-47B56BFB-40AE-4451-A2A8-38C2C5014055Q31146664-4EE0D92E-64F7-4839-8A28-C108696E2409Q33245406-128312EC-DE5A-48C1-8F0C-09CEDA6CAC36Q33269869-A72B71FE-8DA3-47D4-A42D-8BC7C1C19AE0Q33290247-9E5E8851-D9D6-4E55-8EB2-8979067BF8FBQ33298744-364C877E-C0BF-47D7-BF4A-E05F8CFD5AA3Q33346676-D5330EEC-2152-477F-B7CF-D78D819070ECQ33635320-7AA91821-DB62-4FFD-8ABD-352638CC99FFQ33678105-9583B547-451F-4E40-8885-BA53EABD7689
P2860
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年学术文章
@wuu
1996年学术文章
@zh
1996年学术文章
@zh-cn
1996年学术文章
@zh-hans
1996年学术文章
@zh-my
1996年学术文章
@zh-sg
1996年學術文章
@yue
1996年學術文章
@zh-hant
name
The age of Alu subfamilies.
@en
The age of Alu subfamilies.
@nl
type
label
The age of Alu subfamilies.
@en
The age of Alu subfamilies.
@nl
prefLabel
The age of Alu subfamilies.
@en
The age of Alu subfamilies.
@nl
P356
P1476
The age of Alu subfamilies.
@en
P2093
P2888
P356
10.1007/BF00163212
P577
1996-01-01T00:00:00Z