Chromodomain-Mediated Oligomerization of HP1 Suggests a Nucleosome-Bridging Mechanism for Heterochromatin Assembly

Canzio, Daniele; Chang, Evelyn Y.; Shankar, Smita; Kuchenbecker, Kristopher M.; Simon, Matthew D.; Madhani, Hiten D.; Narlikar, Geeta J.; Al-Sady, Bassem

doi:10.1016/j.molcel.2010.12.016

Cited by 274 publications

(399 citation statements)

References 30 publications

(54 reference statements)

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“…In our kinetic model, k + describes the net rate of H3K9me3 addition at nucleosomes immediately adjacent to H3K9me3-marked sites. In this way, spreading of H3K9me3 along the chromosome occurs through linear propagation of the mark to neighboring nucleosomes, consistent with proposed spreading via HP1 oligomerization (5,6,8,21,22). Mechanistically, this propagation likely requires multiple steps (e.g., recruitment of HP1, oligomerization, recruitment of HMT, enzymatic methylation, etc.…”

Section: Resultssupporting

confidence: 78%

“…In mammalian cells, H3K9me3 is associated with heterochromatic and transcriptionally silent regions (1)(2)(3)(4). H3K9me3-based repression requires Heterochromatin Protein 1 (HP1), which mediates cis-spreading of the H3K9me3 mark by binding existing H3K9me3 sites (5-7), oligomerizing to bind neighboring nucleosomes (8,9), and recruiting H3K9-specific histone methyltransferases (HMTs) (10)(11)(12)(13) to induce outward spreading of the mark.…”

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confidence: 99%

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Dynamics of inherently bounded histone modification domains

Hodges

Crabtree

2012

Proc. Natl. Acad. Sci. U.S.A.

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A central goal of chromatin biology is to reveal how posttranslational histone marks modulate gene expression; however, relatively little is known about the spatial or temporal dynamics of these marks. We previously showed that a dynamic model of histone mark nucleation, propagation, and turnover fits the mean enrichment profiles from 99% of noncentromeric histone H3 lysine 9 trimethylation (H3K9me3) domains in mouse embryonic stem cells without the need for boundary or insulator elements. Here we report the full details of this "inherently bounded" model of histone modification dynamics and describe several dynamic features of the model using H3K9me3 as a paradigm. By analyzing the kinetic and structural constraints that drive formation of inherently bounded domains, we find that such domains are optimized when the rates of marking and turnover are comparable. Additionally, we find that to establish such domains, propagation of the histone marks must occur primarily through local contacts.C hromatin is a dynamic environment subject to spatial and temporal regulation through a number of factors. A central focus of this regulation is the posttranslational modification of histone proteins, whose modification states are associated with a variety of transcription states at a given genetic locus. Unfortunately, there are few quantitative models regarding the dynamics of histone marking and therefore little basis for describing the structure, stability, or fluctuations of histone modification domains.One particular posttranslational histone modification, histone H3 lysine 9 trimethylation (H3K9me3), has served as a paradigm to study how histone marks are propagated in live cells to induce local silencing. In mammalian cells, H3K9me3 is associated with heterochromatic and transcriptionally silent regions (1-4). H3K9me3-based repression requires Heterochromatin Protein 1 (HP1), which mediates cis-spreading of the H3K9me3 mark by binding existing H3K9me3 sites (5-7), oligomerizing to bind neighboring nucleosomes (8, 9), and recruiting H3K9-specific histone methyltransferases (HMTs) (10-13) to induce outward spreading of the mark.Unless opposed, this positive feedback would expand H3K9me3-containing domains without bounds. Several groups have described "insulator elements" in flies, yeast, and other organisms, which prevent further expansion of H3K9me3 marking (14). The presence of these insulator elements gives rise to distinct chromatin boundaries, which suggests chromatin may be packaged into modular, independent structural domains near these elements (15). Additionally, in fission yeast, the matingtype locus is silenced through expansion of H3K9me3 over an ∼20-kbp domain with relatively sharp borders (16, 17). The distinct structure of this histone modification domain, with a large plateau and definite borders, indicates that the expansion of H3K9me3 marks is blocked or subject to increased turnover at the border of the domain, consistent with a boundary element.In mammals, however, such expansive H3K9me3 plateaus in ...

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Section: Resultssupporting

confidence: 78%

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confidence: 99%

Dynamics of inherently bounded histone modification domains

Hodges

Crabtree

2012

Proc. Natl. Acad. Sci. U.S.A.

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“…Schizosaccharomyces pombe HP1 displays a 0.12 μM affinity for the H3K9me3-containing nucleosomes (24). We found that the linked PHD fingers of CHD4 bind to the unmodified H3 tails of the tetrasome with the Kds of 0.33 and 0.96 μM, and these affinities are expected to increase significantly upon methylation of Lys9 (a 10-fold increase is seen with H3 peptides alone).…”

Section: Resultsmentioning

confidence: 75%

Bivalent recognition of nucleosomes by the tandem PHD fingers of the CHD4 ATPase is required for CHD4-mediated repression

Musselman

Ramírez

Sims

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

101

131

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CHD4 is a catalytic subunit of the NuRD (nucleosome remodeling and deacetylase) complex essential in transcriptional regulation, chromatin assembly and DNA damage repair. CHD4 contains tandem plant homeodomain (PHD) fingers connected by a short linker, the biological function of which remains unclear. Here we explore the combinatorial action of the CHD4 PHD1/2 fingers and detail the molecular basis for their association with chromatin. We found that PHD1/2 targets nucleosomes in a multivalent manner, concomitantly engaging two histone H3 tails. This robust synergistic interaction displaces HP1γ from pericentric sites, inducing changes in chromatin structure and leading to the dispersion of the heterochromatic mark H3K9me3. We demonstrate that recognition of the histone H3 tails by the PHD fingers is required for repressive activity of the CHD4/NuRD complex. Together, our data elucidate the molecular mechanism of multivalent association of the PHD fingers with chromatin and reveal their critical role in the regulation of CHD4 functions.

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“…Second, enzymes bound to neighboring nucleosomes can interact laterally. Canzio et al showed that the HP1 proteins can form oligomers through chromodomain and chromoshadow domain lateral interactions, and enhanced lateral interactions lead to higher percentage of H3K9me3 (31,32). Interestingly, mutations related to the histone modification enzyme lateral interactions have been reported in cancer cells (33).…”

Section: Identify Puzzle From Experimental Studiesmentioning

confidence: 99%

Computational Modeling to Elucidate Molecular Mechanisms of Epigenetic Memory

Xing

Jin

Zhang

et al. 2015

Epigenetic Technological Applications

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(100-250 words)How do mammalian cells that share the same genome exist in notably distinct phenotypes, exhibiting differences in morphology, gene expression patterns, and epigenetic chromatin statuses? Furthermore how do cells of different phenotypes differentiate reproducibly from a single fertilized egg? These are fundamental problems in developmental biology. Epigenetic histone modifications play an important role in the maintenance of different cell phenotypes. The exact molecular mechanism for inheritance of the modification patterns over cell generations remains elusive. The complexity comes partly from the number of molecular species and the broad time scales involved. In recent years mathematical modeling has made significant contributions on elucidating the molecular mechanisms of DNA methylation and histone Book chapter in Epigenetic Technological Applications (Elsevier), in press 2 covalent modification inheritance. We will pedagogically introduce the typical procedure and some technical details of performing a mathematical modeling study, and discuss future developments. Keywords (5-10)Histone epigenetic memory, mathematical modeling, reader and writer, pattern reconstruction, stochastic dynamics, histone modification enzyme, post-translational modification Outline:In this chapter we discuss how to use mathematical modeling to explore the dynamics and mechanism of histone modification dynamics. Book chapter inEpigenetic Technological Applications (Elsevier), in press 3 Textbody

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Chromodomain-Mediated Oligomerization of HP1 Suggests a Nucleosome-Bridging Mechanism for Heterochromatin Assembly

Cited by 274 publications

References 30 publications

Dynamics of inherently bounded histone modification domains

Dynamics of inherently bounded histone modification domains

Bivalent recognition of nucleosomes by the tandem PHD fingers of the CHD4 ATPase is required for CHD4-mediated repression

Computational Modeling to Elucidate Molecular Mechanisms of Epigenetic Memory

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