A genomic code for nucleosome positioning

Eran Segal; Yvonne Fondufe-Mittendorf; Lingyi Chen; Annchristine Thåström; Yair Field; Irene K. Moore; Ji Ping Z. Wang; Jonathan Widom

doi:10.1038/nature04979

A genomic code for nucleosome positioning

Eran Segal
, Yvonne Fondufe-Mittendorf
, Lingyi Chen
, Annchristine Thåström
, Yair Field
, Irene K. Moore
, Ji Ping Z. Wang
, Jonathan Widom

Molecular and Cellular Biochemistry

Producción científica: Article › revisión exhaustiva

1270 Citas (Scopus)

Resumen

Eukaryotic genomes are packaged into nucleosome particles that occlude the DNA from interacting with most DNA binding proteins. Nucleosomes have higher affinity for particular DNA sequences, reflecting the ability of the sequence to bend sharply, as required by the nucleosome structure. However, it is not known whether these sequence preferences have a significant influence on nucleosome position in vivo, and thus regulate the access of other proteins to DNA. Here we isolated nucleosome-bound sequences at high resolution from yeast and used these sequences in a new computational approach to construct and validate experimentally a nucleosome-DNA interaction model, and to predict the genome-wide organization of nucleosomes. Our results demonstrate that genomes encode an intrinsic nucleosome organization and that this intrinsic organization can explain ∼50% of the in vivo nucleosome positions. This nucleosome positioning code may facilitate specific chromosome functions including transcription factor binding, transcription initiation, and even remodelling of the nucleosomes themselves.

Idioma original	English
Páginas (desde-hasta)	772-778
Número de páginas	7
Publicación	Nature
Volumen	442
N.º	7104
DOI	https://doi.org/10.1038/nature04979
Estado	Published - ago 17 2006

Nota bibliográfica

Funding Information:
Acknowledgements We thank A. Travers for providing the chicken nucleosome core DNA sequences; M. Kubista for providing selected mouse DNA sequences; O. Rando for providing access to their nucleosome data before publication; J. Lieb, E. Nili and P. Jones for sharing their respective unpublished data; Y. Lubling for creating the supplementary website; and H. Chang, N. Friedman, U. Gaul, A. Matouschek, B. Meyer, M. Ptashne, E. Siggia and A. Tanay for useful comments on the manuscript. E.S. was supported by a fellowship from the Center for Studies in Physics and Biology at Rockefeller University and by an NIH grant. J.W. thanks the Center for their hospitality during a sabbatical. J.-P.Z.W. acknowledges support from an NIH grant and J.W. acknowledges support from two NIH grants. E.S. is the incumbent of the Soretta and Henry Shapiro career development chair.

Financiación

Acknowledgements We thank A. Travers for providing the chicken nucleosome core DNA sequences; M. Kubista for providing selected mouse DNA sequences; O. Rando for providing access to their nucleosome data before publication; J. Lieb, E. Nili and P. Jones for sharing their respective unpublished data; Y. Lubling for creating the supplementary website; and H. Chang, N. Friedman, U. Gaul, A. Matouschek, B. Meyer, M. Ptashne, E. Siggia and A. Tanay for useful comments on the manuscript. E.S. was supported by a fellowship from the Center for Studies in Physics and Biology at Rockefeller University and by an NIH grant. J.W. thanks the Center for their hospitality during a sabbatical. J.-P.Z.W. acknowledges support from an NIH grant and J.W. acknowledges support from two NIH grants. E.S. is the incumbent of the Soretta and Henry Shapiro career development chair.

Financiadores	Número del financiador
National Institutes of Health (NIH)
National Childhood Cancer Registry – National Cancer Institute	R01CA119176
Rockefeller University

ASJC Scopus subject areas

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abstract = "Eukaryotic genomes are packaged into nucleosome particles that occlude the DNA from interacting with most DNA binding proteins. Nucleosomes have higher affinity for particular DNA sequences, reflecting the ability of the sequence to bend sharply, as required by the nucleosome structure. However, it is not known whether these sequence preferences have a significant influence on nucleosome position in vivo, and thus regulate the access of other proteins to DNA. Here we isolated nucleosome-bound sequences at high resolution from yeast and used these sequences in a new computational approach to construct and validate experimentally a nucleosome-DNA interaction model, and to predict the genome-wide organization of nucleosomes. Our results demonstrate that genomes encode an intrinsic nucleosome organization and that this intrinsic organization can explain ∼50\% of the in vivo nucleosome positions. This nucleosome positioning code may facilitate specific chromosome functions including transcription factor binding, transcription initiation, and even remodelling of the nucleosomes themselves.",

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A genomic code for nucleosome positioning

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