about
The genome organization of Thermotoga maritima reflects its lifestyleA reexamination of information theory-based methods for DNA-binding site identificationIdentification of primary gene targets of TFAP2C in hormone responsive breast carcinoma cellsMechanisms Underlying the Selection and Function of Macrophage-Specific EnhancersFur controls iron homeostasis and oxidative stress defense in the oligotrophic alpha-proteobacterium Caulobacter crescentusDifferences in microRNA detection levels are technology and sequence dependentTopological characterization of neuronal arbor morphology via sequence representation: I--motif analysisA review of ensemble methods for de novo motif discovery in ChIP-Seq data.PairMotifChIP: A Fast Algorithm for Discovery of Patterns Conserved in Large ChIP-seq Data SetsMATLIGN: a motif clustering, comparison and matching tool.Comprehensive analysis of co-occurring domain sets in yeast proteins.FISim: a new similarity measure between transcription factor binding sites based on the fuzzy integralMany sequence-specific chromatin modifying protein-binding motifs show strong positional preferences for potential regulatory regions in the Saccharomyces cerevisiae genomeMochiView: versatile software for genome browsing and DNA motif analysis.Cooperation between a hierarchical set of recruitment sites targets the X chromosome for dosage compensationDMINDA: an integrated web server for DNA motif identification and analysesA ChIP-Seq benchmark shows that sequence conservation mainly improves detection of strong transcription factor binding sites.Discovery of protein phosphorylation motifs through exploratory data analysis.Rewiring of PDZ domain-ligand interaction network contributed to eukaryotic evolution.Differences in local genomic context of bound and unbound motifs.Pinpointing transcription factor binding sites from ChIP-seq data with SeqSite.Cell-type specificity of ChIP-predicted transcription factor binding sitesComprehensive human transcription factor binding site map for combinatory binding motifs discovery.Ebolavirus Database: Gene and Protein Information Resource for EbolavirusesHow does DNA sequence motif discovery work?Patterns and evolution of ACGT repeat cis-element landscape across four plant genomesLoss of the Notch effector RBPJ promotes tumorigenesis.RNA-Seq analysis of splicing in Plasmodium falciparum uncovers new splice junctions, alternative splicing and splicing of antisense transcriptsIdentifying transcriptional cis-regulatory modules in animal genomes.DECOD: fast and accurate discriminative DNA motif findingRNA-Seq Analysis of Differential Splice Junction Usage and Intron Retentions by DEXSeqLocal slowdown of translation by nonoptimal codons promotes nascent-chain recognition by SRP in vivo.Intersecting transcription networks constrain gene regulatory evolutionPDZ domain-containing 1 (PDZK1) protein regulates phospholipase C-β3 (PLC-β3)-specific activation of somatostatin by forming a ternary complex with PLC-β3 and somatostatin receptorsInference of self-regulated transcriptional networks by comparative genomicsAn algorithmic perspective of de novo cis-regulatory motif finding based on ChIP-seq data.Why transcription factor binding sites are ten nucleotides long.Information-theoretic uncertainty of SCFG-modeled folding space of the non-coding RNA.The antioxidant/electrophile response element motif.Saturation scanning of ubiquitin variants reveals a common hot spot for binding to USP2 and USP21
P2860
Q21092408-706A98FF-5CF3-4B56-BD43-36EB56E77970Q21284367-E36E661B-7719-48CD-A596-C7CCC0C21739Q24626014-D5BE8F4D-FC79-42D6-8431-BE540815E665Q27006789-7697B37E-2B58-472B-918D-7B124FE804F5Q29346523-682326C2-D606-46CC-8CBD-7A4E6DC86CFBQ30540469-94807136-5FE0-4A79-A3E2-ABED49E0E979Q30657254-C0C6E7A6-1930-4539-9B56-6B4A67606492Q30936358-5645FFF2-6D50-4628-87DF-847CE1CBFCF1Q31142318-6098539A-4076-4F28-B7E0-5BC8BCB33BC4Q33287216-F6D3034D-3F35-4B6D-B474-12214BC0EED0Q33287350-49ACDBBA-6CD3-441A-A288-2BA70F001EAEQ33483738-2BA5CCD4-4953-4BF3-B1E6-4B4C7E8B1CAEQ33521810-070ADA86-026F-4959-9FD1-ECF0028F868EQ33561311-6354803E-EECD-4017-BEA9-55D6887F418FQ33746443-AAD7178C-60E3-41C0-8E83-10EAFE0820D3Q33860675-327367C2-E302-483B-BC7B-5DF1858A4D09Q33886721-97AC5A54-58E1-4B6C-8E4C-B11EB84AA421Q33925380-D7BF7348-2938-4F03-85DB-686094F85E0FQ34162330-9E2A4287-4F87-4BF7-988E-0A0DD2F8CB7EQ34301632-D543A551-D508-4CDD-9B85-2FEBAA9348A3Q34333439-69CEEF07-EC78-4DA7-93CE-5A0D2D16E25FQ34365955-FCE3781D-6CC0-4E88-A024-5AB00DCBDAEDQ34499593-89908005-38C2-4AF8-9479-67B7C8F157A1Q34527039-2B749BCD-E25E-4D29-AED2-AB086EA1BE70Q34569841-310321DF-A17C-4328-B30C-69E297298FE2Q34636567-C5DB339A-BED9-4DDC-B3DC-C1D2ABB96B0CQ34924659-9449BC4D-79BC-49E4-B674-6EE44549FAFBQ34946799-ED93D13A-02C3-4DAB-BAD7-8890AC2E3F98Q35117066-14B1AE4D-71A6-4658-9FDE-6BFBF73E1777Q35170092-372EE93B-B478-44B4-90C3-1C2328A08BCBQ35761182-94ADDD8D-E511-464F-BFE4-0C7F43B0C71BQ35809145-41FFF1C1-CEE3-404A-9A4B-C13B7C6998D6Q35935784-C5689F30-39E0-41CE-86EA-A59E9B1A3546Q36033180-0EAF074A-5FCB-49AC-8C46-54060AFF4D7FQ36173192-4A70646F-824E-4B62-9F30-9315C1E29AB3Q36320368-9E580E4E-E870-4E80-90BA-AA111BD8A316Q36466353-005C7594-D5EC-4D65-B660-415274BF25C6Q36514140-771835AB-DED5-4D8F-B9A6-B7FE235B9CD4Q36761692-E3ABC6A0-8B54-4844-83AC-3AB710F0CAEFQ37161666-05E0CBD1-432A-4284-AD62-D24253C8FECD
P2860
description
2006 nî lūn-bûn
@nan
2006 թուականի Ապրիլին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի ապրիլին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年論文
@yue
2006年論文
@zh-hant
2006年論文
@zh-hk
2006年論文
@zh-mo
2006年論文
@zh-tw
2006年论文
@wuu
name
What are DNA sequence motifs?
@ast
What are DNA sequence motifs?
@en
What are DNA sequence motifs?
@nl
type
label
What are DNA sequence motifs?
@ast
What are DNA sequence motifs?
@en
What are DNA sequence motifs?
@nl
prefLabel
What are DNA sequence motifs?
@ast
What are DNA sequence motifs?
@en
What are DNA sequence motifs?
@nl
P2860
P356
P1433
P1476
What are DNA sequence motifs?
@en
P2860
P2888
P304
P356
10.1038/NBT0406-423
P577
2006-04-01T00:00:00Z
P5875
P6179
1020671712