Variation in Transcription Factor Binding Among Humans

Like Father, Like Mother, Like Child Transcriptional regulation is mediated by chromatin structure, which may affect the binding of transcription factors, but the extent of how individual-to-individual genetic variation affects such regulation is not well understood. Kasowski et al. (p. 232, published online 18 March) investigated the binding of two transcription factors across the genomes of human individuals and one chimpanzee. Transcription factor binding was associated with genomic features such as nucleotide variation, insertions and deletions, and copy number variation. Thus, genomic sequence variation affects transcription factor binding and may explain expression difference among individuals. McDaniell et al. (p. 235, published online 18 March) provide a genome-wide catalog of variation in chromatin and transcription factor binding in two parent-child trios of European and African ancestry. Up to 10% of active chromatin binding sites were specific to a set of individuals and were often inherited. Furthermore, variation in active chromatin sites showed heritable allele-specific correlation with variation in gene expression. Transcription factor binding sites vary among individuals and are correlated with differences in expression. Differences in gene expression may play a major role in speciation and phenotypic diversity. We examined genome-wide differences in transcription factor (TF) binding in several humans and a single chimpanzee by using chromatin immunoprecipitation followed by sequencing. The binding sites of RNA polymerase II (PolII) and a key regulator of immune responses, nuclear factor κB (p65), were mapped in 10 lymphoblastoid cell lines, and 25 and 7.5% of the respective binding regions were found to differ between individuals. Binding differences were frequently associated with single-nucleotide polymorphisms and genomic structural variants, and these differences were often correlated with differences in gene expression, suggesting functional consequences of binding variation. Furthermore, comparing PolII binding between humans and chimpanzee suggests extensive divergence in TF binding. Our results indicate that many differences in individuals and species occur at the level of TF binding, and they provide insight into the genetic events responsible for these differences.

[1]  E. Birney,et al.  Heritable Individual-Specific and Allele-Specific Chromatin Signatures in Humans , 2010, Science.

[2]  Daniel A. Skelly,et al.  Inherited variation in gene expression. , 2009, Annual review of genomics and human genetics.

[3]  Raymond K. Auerbach,et al.  PeakSeq enables systematic scoring of ChIP-seq experiments relative to controls , 2009, Nature Biotechnology.

[4]  Joshua M. Korn,et al.  Integrated detection and population-genetic analysis of SNPs and copy number variation , 2008, Nature Genetics.

[5]  Joshua M. Korn,et al.  Mapping and sequencing of structural variation from eight human genomes , 2008, Nature.

[6]  Philip M. Kim,et al.  Paired-End Mapping Reveals Extensive Structural Variation in the Human Genome , 2007, Science.

[7]  Zhaohui S. Qin,et al.  A second generation human haplotype map of over 3.1 million SNPs , 2007, Nature.

[8]  Timothy B. Stockwell,et al.  The Diploid Genome Sequence of an Individual Human , 2007, PLoS biology.

[9]  Mark Gerstein,et al.  Divergence of transcription factor binding sites across related yeast species. , 2007, Science.

[10]  R. Redon,et al.  Relative Impact of Nucleotide and Copy Number Variation on Gene Expression Phenotypes , 2007, Science.

[11]  L. Kruglyak,et al.  Genetics of global gene expression , 2006, Nature Reviews Genetics.

[12]  R. Stauber,et al.  Acetylation of Stat1 modulates NF-B activity , 2006 .

[13]  Philipp Khaitovich,et al.  Human brain evolution. , 2006, Progress in brain research.

[14]  E. Eichler,et al.  Fine-scale structural variation of the human genome , 2005, Nature Genetics.

[15]  M. Hattori,et al.  DNA sequence and comparative analysis of chimpanzee chromosome 22 , 2004, Nature.

[16]  Wyeth W. Wasserman,et al.  JASPAR: an open-access database for eukaryotic transcription factor binding profiles , 2004, Nucleic Acids Res..

[17]  G. Condorelli,et al.  The B Subunit of the CAAT-binding Factor NFY Binds the Central Segment of the Co-activator p300* , 1999, The Journal of Biological Chemistry.