Proteome-wide Analysis in Saccharomyces cerevisiae Identifies Several PHD Fingers as Novel Direct and Selective Binding Modules of Histone H3 Methylated at Either Lysine 4 or Lysine 36

Xiaobing Shi; Ioulia Kachirskaia; Kay L. Walter; Jen-Hao A. Kuo; Aimee Lake; Foteini Davrazou; Steve M. Chan; David G. Martin; Ian M. Fingerman; Scott Briggs; LeAnn Howe; Paul J. Utz; Tatiana G. Kutateladze; Alexey A. Lugovskoy; Mark T. Bedford; Or Gozani

doi:10.1074/jbc.c600286200

Proteome-wide Analysis in Saccharomyces cerevisiae Identifies Several PHD Fingers as Novel Direct and Selective Binding Modules of Histone H3 Methylated at Either Lysine 4 or Lysine 36

Xiaobing Shi(Stanford University), Ioulia Kachirskaia(Purdue University West Lafayette), Kay L. Walter(Purdue University West Lafayette), Jen-Hao A. Kuo(Purdue University West Lafayette), Aimee Lake(The University of Texas MD Anderson Cancer Center), Foteini Davrazou(University of Colorado Hospital), Steve M. Chan(Stanford Medicine), David G. Martin(University of British Columbia), Ian M. Fingerman(Purdue University West Lafayette), Scott Briggs(Purdue University West Lafayette), LeAnn Howe(University of British Columbia), Paul J. Utz(Stanford University), Tatiana G. Kutateladze(University of Colorado Hospital), Alexey A. Lugovskoy(The University of Texas MD Anderson Cancer Center), Mark T. Bedford(The University of Texas MD Anderson Cancer Center), Or Gozani(Stanford University)

Journal of Biological Chemistry

December 2, 2006

10.1074/jbc.c600286200

Cited by 257Open Access

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Abstract

The PHD finger motif is a signature chromatin-associated motif that is found throughout eukaryotic proteomes. Here we have determined the histone methyl-lysine binding activity of the PHD fingers present within the Saccharomyces cerevisiae proteome. We provide evidence on the genomic scale that PHD fingers constitute a general class of effector modules for histone H3 trimethylated at lysine 4 (H3K4me3) and histone H3 trimethylated at lysine 36 (H3K36me3). Structural modeling of PHD fingers demonstrates a conserved mechanism for recognizing the trimethyl moiety and provides insight into the molecular basis of affinity for the different methyl-histone ligands. Together, our study suggests that a common function for PHD fingers is to transduce methyl-lysine events and sheds light on how a single histone modification can be linked to multiple biological outcomes.

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