10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
about
Inferring horizontal gene transferSequence periodicity of Escherichia coli is concentrated in intergenic regionsA-tract clusters may facilitate DNA packaging in bacterial nucleoid.Genomes are covered with ubiquitous 11 bp periodic patterns, the "class A flexible patterns".Survey of extrachromosomal circular DNA derived from plant satellite repeatsStructural analysis of DNA sequence: evidence for lateral gene transfer in Thermotoga maritimaProtein folding: looping from hydrophobic nuclei.Analysis of distribution indicates diverse functions of simple sequence repeats in Mycoplasma genomes.Wavelet Analysis of DNA Bending Profiles reveals Structural Constraints on the Evolution of Genomic Sequences.The global intrinsic curvature of archaeal and eubacterial genomes is mostly contained in their dinucleotide composition and is probably not an adaptation.Sequence-dependent histone variant positioning signaturesAnalysis of nucleosome positioning determined by DNA helix curvature in the human genome.The structural code of cyanobacterial genomes.Differences in DNA curvature-related sequence periodicity between prokaryotic chromosomes and phages, and relationship to chromosomal prophage contentInvestigating the interplay between nucleoid-associated proteins, DNA curvature, and CRISPR elements using comparative genomics.PerPlot & PerScan: tools for analysis of DNA curvature-related periodicity in genomic nucleotide sequencesBiological consequences of tightly bent DNA: the other life of a macromolecular celebrity.Characteristics of nucleosome core DNA and their applications in predicting nucleosome positions.Database of Periodic DNA Regions in Major Genomes.Efficient translation initiation dictates codon usage at gene start.TAREAN: a computational tool for identification and characterization of satellite DNA from unassembled short reads.Categorical spectral analysis of periodicity in nucleosomal DNA.Adaptive machine learning technique for periodicity detection in biological sequences.Periodic power spectrum with applications in detection of latent periodicities in DNA sequences.Gene prediction by spectral rotation measure: a new method for identifying protein-coding regions.Comparative analysis of sequence periodicity among prokaryotic genomes points to differences in nucleoid structure and a relationship to gene expression.Promoter protection by a transcription factor acting as a local topological homeostatNucleosome positioning pattern derived from oligonucleotide compositions of genomic sequences.Statistics of DNA sequences: a low-frequency analysis.Tracing ancient mRNA hairpins.Three sequence rules for chromatin.Informational structure of two closely related eukaryotic genomes.Yeast nucleosome DNA pattern: deconvolution from genome sequences of S. cerevisiae.Recurrence time statistics: versatile tools for genomic DNA sequence analysis.Sequence-related human proteins cluster by degree of evolutionary conservation.The Major Architects of Chromatin: Architectural Proteins in Bacteria, Archaea and Eukaryotes
P2860
Q21045419-7E756D07-6A02-4DBF-B125-9B6F6F3A06F2Q24806292-87ED20D5-9569-4E5A-8E98-CE08BF3C3F28Q24812830-9E54BD00-448D-40D9-915D-E5417E6335D3Q24814573-4CDCFC8A-63CE-4179-8CCF-F31C9C77BDC8Q27496637-9B894C56-9902-49D5-A387-23B4E5A6EB2EQ30002350-C6FF5C6F-F857-421A-BDF1-8218A13FB927Q30329263-0FE7078F-884C-4752-8C84-A23CE6E8B726Q30353931-F628D43C-AD6B-45FF-B320-B551057803B8Q30458944-C372FFCC-7030-4E8C-AE5F-0CDF008F8CB6Q33618342-A49B6306-258A-481F-AABA-5943768F0745Q33766756-ADFAC294-2B1F-49A8-8E45-3B153CC63BE2Q33804573-2CFED89F-387E-429F-BEB5-00921AA3E44BQ34044460-F6B1DF79-7689-4FC6-80CE-1E439789DC29Q34269649-57D0E844-77D9-451E-9EE2-BF61345A7F23Q35111312-BE38931E-C93B-4B33-BD85-66E17FA6622BQ36023382-39761829-6B4B-455A-BA2F-A4F5721F785CQ36395025-D4C11DEB-A7F1-467B-B76B-CFAF3D42014AQ36678205-24A1FAC4-F4C3-4F9D-8C93-764ED3A55756Q37611313-92C20B1F-C1B6-40B4-B22D-7CFFE82FEA1EQ38461794-DE173120-A2FB-49C3-8B32-5B69AC767A8DQ38840582-BFAD6F59-4234-497E-8791-1C38BE63EA99Q39143137-A8CD902B-CB4C-4A99-9B5E-94374B3B56BFQ39278017-AB61F566-146C-4F84-AEF4-20F580D11A9BQ40357196-88F87268-69A6-44CD-ABBC-B063ED9D2CBAQ40830416-66780642-DA89-4CED-B623-41DA1BA8804AQ41943411-870279FA-FF7B-4DA8-80C3-D3C7F5AE2D5FQ41992041-0ABC0A5F-88ED-4F6D-92D1-40F37C6E65D0Q44144466-040D47BA-6189-4A12-9B85-4CC021FD48A4Q46319000-816C901F-CAF6-43DA-B0EA-F2CAAA0EA11AQ47189549-E0B5D48A-4D20-4CBA-B528-3461BECF78C7Q48098895-E8A5ABA6-8445-4824-8E4D-3E5D1862E759Q51123119-9860AFC9-2033-408F-834D-32C324937162Q51496632-2F0B4145-AE1C-4DF3-B180-E55237549D1FQ51966252-898E77BE-3425-4341-8973-722FAE1B7B0CQ52941165-6A031369-38E3-4C7E-8108-0CBFBA07ACC0Q58286818-FB6BE456-A35E-4E91-A641-3D651A586FB2
P2860
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
description
1999 nî lūn-bûn
@nan
1999 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
1999 թվականի մարտին հրատարակված գիտական հոդված
@hy
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
name
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@ast
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@en
type
label
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@ast
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@en
prefLabel
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@ast
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@en
P2093
P356
P1433
P1476
10-11 bp periodicities in complete genomes reflect protein structure and DNA folding.
@en
P2093
P304
P356
10.1093/BIOINFORMATICS/15.3.187
P407
P577
1999-03-01T00:00:00Z