Recombination drives the evolution of GC-content in the human genome.
about
Forces shaping the fastest evolving regions in the human genomeHotspots of biased nucleotide substitutions in human genesGenome analysis of the platypus reveals unique signatures of evolutionComparison of the chicken and turkey genomes reveals a higher rate of nucleotide divergence on microchromosomes than macrochromosomesContrasting GC-content dynamics across 33 mammalian genomes: relationship with life-history traits and chromosome sizesThe role of GC-biased gene conversion in shaping the fastest evolving regions of the human genomeNucleotide-resolution analysis of structural variants using BreakSeq and a breakpoint libraryBoth selective and neutral processes drive GC content evolution in the human genomeNoncoding DNA, isochores and gene expression: nucleosome formation potentialRecombination and base composition: the case of the highly self-fertilizing plant Arabidopsis thalianaGenomic and proteomic adaptations to growth at high temperatureMammalian BEX, WEX and GASP genes: coding and non-coding chimaerism sustained by gene conversion eventsEmergence, Retention and Selection: A Trilogy of Origination for Functional De Novo Proteins from Ancestral LncRNAs in PrimatesStable recombination hotspots in birdsThe relationship of recombination rate, genome structure, and patterns of molecular evolution across angiospermsThree tiers of genome evolution in reptilesRapid evolution of Beta-keratin genes contribute to phenotypic differences that distinguish turtles and birds from other reptilesSubstitution patterns are under different influences in primates and rodentsDynamic evolution of base composition: causes and consequences in avian phylogenomicsThe recombination landscape of the zebra finch Taeniopygia guttata genomeMolecular evolution of genes in avian genomesThe mutational spectrum of non-CpG DNA varies with CpG contentEvolutionary rate variation in Old World monkeysThe chicken (Gallus gallus) Z chromosome contains at least three nonlinear evolutionary strataCpG dinucleotides and the mutation rate of non-CpG DNAHeterogeneous genomic molecular clocks in primatesVariable molecular clocks in hominoids.Statistical signals in bioinformatics.Amino acid composition in endothermic vertebrates is biased in the same direction as in thermophilic prokaryotes.Length and GC content variability of introns among teleostean genomes in the light of the metabolic rate hypothesisThe genomic distribution of intraspecific and interspecific sequence divergence of human segmental duplications relative to human/chimpanzee chromosomal rearrangements.Codon usage is associated with the evolutionary age of genes in metazoan genomes.The scale of mutational variation in the murid genomePhase distribution of spliceosomal introns: implications for intron origin.Directionality of point mutation and 5-methylcytosine deamination rates in the chimpanzee genome.Base-compositional heterogeneity in the RAG1 locus among didelphid marsupials: implications for phylogenetic inference and the evolution of GC content.Mutations of different molecular origins exhibit contrasting patterns of regional substitution rate variation.The impact of recombination on nucleotide substitutions in the human genomeHighly conserved regimes of neighbor-base-dependent mutation generated the background primary-structural heterogeneities along vertebrate chromosomes.Partial correlation analysis indicates causal relationships between GC-content, exon density and recombination rate in the human genome.
P2860
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P2860
Recombination drives the evolution of GC-content in the human genome.
description
2004 nî lūn-bûn
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2004年の論文
@ja
2004年学术文章
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2004年学术文章
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2004年学术文章
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2004年学术文章
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2004年學術文章
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name
Recombination drives the evolution of GC-content in the human genome.
@en
Recombination drives the evolution of GC-content in the human genome.
@nl
type
label
Recombination drives the evolution of GC-content in the human genome.
@en
Recombination drives the evolution of GC-content in the human genome.
@nl
prefLabel
Recombination drives the evolution of GC-content in the human genome.
@en
Recombination drives the evolution of GC-content in the human genome.
@nl
P356
P1476
Recombination drives the evolution of GC-content in the human genome
@en
P2093
Julien Meunier
P304
P356
10.1093/MOLBEV/MSH070
P577
2004-02-12T00:00:00Z