Catalytic and non-catalytic mechanisms of histone H4 lysine 20 methyltransferase SUV420H1

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Both combinatorial K4me0-K36me3 marks on sister histone H3s of a nucleosome are required for Dnmt3a-Dnmt3L mediated de novo DNA methylation

A nucleosome contains two copies of each histone H2A,H2B,H3 and H4.Histone H3 K4me0 and K36me3are two key chromatin marks for de novo DNA methylation catalyzed by DNA methyltransferases in mammals.However,it remains unclear whether K4me0 and K36me3 marks on both sister histone H3s regulate de novo DNA methylation independently or cooperatively.Here,taking advantage of the bivalent histone H3 system in yeast,we examined the contributions of K4 and K36 on sister histone H3s to genomic DNA methylation catalyzed by ectopically co-expressed murine Dnmt3a and Dnmt3L.The results show that lack of both K4me0 and K36me3 on one sister H3 tail,or lack of K4me0 and K36me3 on respective sister H3s results in a dramatic reduction of 5mC,revealing a synergy of two sister H3s in DNA methylation regulation.Accordingly,the Dnmt3a or Dnmt3L mutation that disrupts the interaction of Dnmt3aADD domain-H3K4me0,Dnmt3LADD domain-H3K4me0,orDnmt3aPWWP domain-H3K36me3 causes a significant reduction of DNA methylation.These results support the model that each heterodimeric Dnmt3a-Dnmt3L reads both K4me0 and K36me3 marks on one tail of sister H3s,and the dimer of heterodimeric Dnmt3a-Dnmt3L recognizes two tails of sister histone H3s to efficiently execute de novo DNA methylation.     

组蛋白赖氨酸甲基化在表观遗传调控中的作用

组蛋白赖氨酸的甲基化在表观遗传调控中起着关键作用。组蛋白H3的K4、K9、K27、K36、K79和H4的K20均可被甲基化。组蛋白H3第9位赖氨酸的甲基化与基因的失活相关连; 组蛋白H3第4位赖氨酸和第36位赖氨酸的甲基化与基因的激活相关连; 组蛋白H3第27位赖氨酸的甲基化与同源盒基因沉默、X染色体失活、基因印记等基因沉默现象有关; 组蛋白H3第79位赖氨酸的甲基化与防止基因失活和DNA修复有关。与此同时, 组蛋白的去甲基化也受到更为广泛的关注。 关键词: 组蛋白赖氨酸甲基转移酶; 组蛋白赖氨酸甲基化; 组蛋白去甲基化     

Probe the function of histone lysine 36 methylation using histone H3 lysine 36 to methionine mutant transgene in mammalian cells

Chondroblastoma is a cartilaginous tumor that typically arises under 25 y of age (80%). Recent studies have identified a somatic and heterozygous mutation at the H3F3B gene in over 90% chondroblastoma cases, leading to a lysine 36 to methionine replacement (H3.3K36M). In human cells, H3F3B gene is one of 2 genes that encode identical H3.3 proteins. It is not known how H3.3K36M mutant proteins promote tumorigenesis. We and others have shown that, the levels of H3K36 di- and tri-methylation (H3K36me2/me3) are reduced dramatically in chondroblastomas and chondrocytes bearing the H3.3K36M mutation. Mechanistically, H3.3K36M mutant proteins inhibit enzymatic activity of some, but not all H3K36 methyltransferases. Chondrocytes harboring the same H3F3B mutation exhibited the cancer cell associated phenotypes. Here, we discuss the potential effects of H3.3K36M mutation on epigenomes including H3K36 and H3K27 methylation and cellular phenotypes. We suggest that H3.3K36M mutant proteins alter epigenomes of specific progenitor cells, which in turn lead to cellular transformation and tumorigenesis.     

Histone H4K20 Demethylation by Two hHR23 Proteins

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Histone H4K20 tri‐methylation at late‐firing origins ensures timely heterochromatin replication

Among other targets, the protein lysine methyltransferase PR‐Set7 induces histone H4 lysine 20 monomethylation (H4K20me1), which is the substrate for further methylation by the Suv4‐20h methyltransferase. Although these enzymes have been implicated in control of replication origins, the specific contribution of H4K20 methylation to DNA replication remains unclear. Here, we show that H4K20 mutation in mammalian cells, unlike in Drosophila, partially impairs S‐phase progression and protects from DNA re‐replication induced by stabilization of PR‐Set7. Using Epstein–Barr virus‐derived episomes, we further demonstrate that conversion of H4K20me1 to higher H4K20me2/3 states by Suv4‐20h is not sufficient to define an efficient origin per se, but rather serves as an enhancer for MCM2‐7 helicase loading and replication activation at defined origins. Consistent with this, we find that Suv4‐20h‐mediated H4K20 tri‐methylation (H4K20me3) is required to sustain the licensing and activity of a subset of ORCA/LRWD1‐associated origins, which ensure proper replication timing of late‐replicating heterochromatin domains. Altogether, these results reveal Suv4‐20h‐mediated H4K20 tri‐methylation as a critical determinant in the selection of active replication initiation sites in heterochromatin regions of mammalian genomes.     

The SET8 H4K20 protein lysine methyltransferase has a long recognition sequence covering seven amino acid residues

The SET8 histone lysine methyltransferase, which monomethylates the histone 4 lysine 20 residue plays important roles in cell cycle control and genomic stability. By employing peptide arrays we have shown that it has a long recognition sequence motif covering seven amino acid residues, viz. R¹⁷–H¹⁸–(R¹⁹KY)–K²⁰–(V²¹ILFY)–(L²²FY)–R²³. Celluspots peptide array methylation studies confirmed specific monomethylation of H4K20 and revealed that the symmetric and asymmetric methylation on R¹⁷ of the H4 tail inhibits methylation on H4K20. Similarly, dimethylation of the R located at the −3 position also reduced methylation of p53 K382 which had been shown previously to be methylated by SET8. Based on the derived specificity profile, we identified 4 potential non-histone substrate proteins. After relaxing the specificity profile, we identified several more candidate substrates and showed efficient methylation of 20 novel non-histone peptides by SET8. However, apart from H4 and p53 none of the identified novel peptide targets was methylated at the protein level. Since H4 and p53 both contain the target lysine in an unstructured part of the protein, we conclude that the long recognition sequence of SET8 makes it difficult to methylate a lysine in a folded region of a protein, because amino acid side chains essential for recognition will be buried.     

The profile of repeat-associated histone lysine methylation states in the mouse epigenome

Histone lysine methylation has been shown to index silenced chromatin regions at, for example, pericentric heterochromatin or of the inactive X chromosome. Here, we examined the distribution of repressive histone lysine methylation states over the entire family of DNA repeats in the mouse genome. Using chromatin immunoprecipitation in a cluster analysis representing repetitive elements, our data demonstrate the selective enrichment of distinct H3-K9, H3-K27 and H4-K20 methylation marks across tandem repeats (e.g. major and minor satellites), DNA transposons, retrotransposons, long interspersed nucleotide elements and short interspersed nucleotide elements. Tandem repeats, but not the other repetitive elements, give rise to double-stranded (ds) RNAs that are further elevated in embryonic stem (ES) cells lacking the H3-K9-specific Suv39h histone methyltransferases. Importantly, although H3-K9 tri- and H4-K20 trimethylation appear stable at the satellite repeats, many of the other repeat-associated repressive marks vary in chromatin of differentiated ES cells or of embryonic trophoblasts and fibroblasts. Our data define a profile of repressive histone lysine methylation states for the repetitive complement of four distinct mouse epigenomes and suggest tandem repeats and dsRNA as primary triggers for more stable chromatin imprints.     

Smyd3 regulates cancer cell phenotypes and catalyzes histone H4 lysine 5 methylation

Smyd3 is a lysine methyltransferase implicated in chromatin and cancer regulation. Here we show that Smyd3 catalyzes histone H4 methylation at lysine 5 (H4K5me). This novel histone methylation mark is detected in diverse cell types and its formation is attenuated by depletion of Smyd3 protein. Further, Smyd3-driven cancer cell phenotypes require its enzymatic activity. Thus, Smyd3, via H4K5 methylation, provides a potential new link between chromatin dynamics and neoplastic disease.     

Smyd3 regulates cancer cell phenotypes and catalyzes histone H4 lysine 5 methylation

Smyd3 is a lysine methyltransferase implicated in chromatin and cancer regulation. Here we show that Smyd3 catalyzes histone H4 methylation at lysine 5 (H4K5me). This novel histone methylation mark is detected in diverse cell types and its formation is attenuated by depletion of Smyd3 protein. Further, Smyd3-driven cancer cell phenotypes require its enzymatic activity. Thus, Smyd3, via H4K5 methylation, provides a potential new link between chromatin dynamics and neoplastic disease.     

Charge-based interaction conserved within histone H3 lysine 4 (H3K4) methyltransferase complexes is needed for protein stability, histone methylation, and gene expression

Histone H3 lysine 4 (H3K4) methyltransferases are conserved from yeast to humans, assemble in multisubunit complexes, and are needed to regulate gene expression. The yeast H3K4 methyltransferase complex, Set1 complex or complex of proteins associated with Set1 (COMPASS), consists of Set1 and conserved Set1-associated proteins: Swd1, Swd2, Swd3, Spp1, Bre2, Sdc1, and Shg1. The removal of the WD40 domain-containing subunits Swd1 and Swd3 leads to a loss of Set1 protein and consequently a complete loss of H3K4 methylation. However, until now, how these WD40 domain-containing proteins interact with Set1 and contribute to the stability of Set1 and H3K4 methylation has not been determined. In this study, we identified small basic and acidic patches that mediate protein interactions between the C terminus of Swd1 and the nSET domain of Set1. Absence of either the basic or acidic patches of Set1 and Swd1, respectively, disrupts the interaction between Set1 and Swd1, diminishes Set1 protein levels, and abolishes H3K4 methylation. Moreover, these basic and acidic patches are also important for cell growth, telomere silencing, and gene expression. We also show that the basic and acidic patches of Set1 and Swd1 are conserved in their human counterparts SET1A/B and RBBP5, respectively, and are needed for the protein interaction between SET1A and RBBP5. Therefore, this charge-based interaction is likely important for maintaining the protein stability of the human SET1A/B methyltransferase complexes so that proper H3K4 methylation, cell growth, and gene expression can also occur in mammals.     

A plant‐specific histone H3 lysine 4 demethylase represses the floral transition in Arabidopsis

Histone demethylation regulates chromatin structure and gene expression, and is catalyzed by various histone demethylases. Trimethylation of histone H3 at lysine 4 (H3K4) is coupled to active gene expression; trimethyl H3K4 is demethylated by Jumonj C (JmjC) domain‐containing demethylases in mammals. Here we report that a plant‐specific JmjC domain‐containing protein known as PKDM7B (At4g20400) demethylates trimethyl H3K4. PKDM7B mediates H3K4 demethylation in a key floral promoter, FLOWERING LOCUS T (FT), and an FT homolog, TWIN SISTER OF FT (TSF), and represses their expression to inhibit the floral transition in Arabidopsis. Our findings suggest that there are at least two distinct sub‐families of JmjC domain‐containing demethylases that demethylate the active trimethyl H3K4 mark in eukaryotic genes, and reveal a plant‐specific JmjC domain enzyme capable of H3K4 demethylation.     

Isolation and characterization of histone H3 lysine 4 demethylase-containing complexes

Histone methylation is involved in the regulation of many cellular processes. In the past 2 years, several histone demethylases including BHC110/LSD1 have been characterized. BHC110, the first known histone lysine demethylase, removes methyl groups from methylated histone H3 lysine 4 and has been found in many multi-protein complexes. Using one-step affinity purification, we have isolated enzymatically active BHC110-containing complexes. Here, we detail the methods used for the isolation and characterization of these histone demethylase complexes from a human stable cell line.     

Mechanisms of histone H3 lysine 27 trimethylation remodeling during early mammalian development

During fertilization, two of the most differentiated cells in the mammalian organism, a sperm and oocyte, are combined to form a pluripotent embryo. Dynamic changes in chromatin structure allow the transition of the chromatin on these specialized cells into an embryonic configuration capable of generating every cell type. Initially, this reprogramming activity is supported by oocyte-derived factors accumulated during oogenesis as proteins and mRNAs; however, the underlying molecular mechanisms that govern it remain poorly characterized. Trimethylation of histone H3 at lysine 27 (H3K27me3) is a repressive epigenetic mark that changes dynamically during pre-implantation development in mice, bovine and pig embryos. Here we present data and hypotheses related to the potential mechanisms behind H3K27me3 remodeling during early development. We postulate that the repressive H3K27me3 mark is globally erased from the parental genomes in order to remove the gametic epigenetic program and to establish a pluripotent embryonic epigenome. We discuss information gathered in mice, pigs, and bovine, with the intent of providing a comparative analysis of the reprogramming of this epigenetic mark during early mammalian development.     

Mechanisms of histone H3 lysine 27 trimethylation remodeling during early mammalian development

During fertilization, two of the most differentiated cells in the mammalian organism, a sperm and oocyte, are combined to form a pluripotent embryo. Dynamic changes in chromatin structure allow the transition of the chromatin on these specialized cells into an embryonic configuration capable of generating every cell type. Initially, this reprogramming activity is supported by oocyte-derived factors accumulated during oogenesis as proteins and mRNAs; however, the underlying molecular mechanisms that govern it remain poorly characterized. Trimethylation of histone H3 at lysine 27 (H3K27me3) is a repressive epigenetic mark that changes dynamically during pre-implantation development in mice, bovine and pig embryos. Here we present data and hypotheses related to the potential mechanisms behind H3K27me3 remodeling during early development. We postulate that the repressive H3K27me3 mark is globally erased from the parental genomes in order to remove the gametic epigenetic program and to establish a pluripotent embryonic epigenome. We discuss information gathered in mice, pigs, and bovine, with the intent of providing a comparative analysis of the reprogramming of this epigenetic mark during early mammalian development.     

Dynamics of H3K27me3 methylation and demethylation in plant development

Epigenetic regulation controls multiple aspects of the plant development. The N-terminal tail of histone can be differently modified to regulate various chromatin activities. One of them, the trimethylation of histone H3 lysine 27 (H3K27me3) confers a repressive chromatin state with gene silencing. H3K27me3 is dynamically deposited and removed throughout development. While components of the H3K27me3 writer, Polycomb repressive complex 2 (PRC2), have been reported for almost 2 decades, it is only recently that JUMONJI (JMJ) proteins are reported as H3K27me3 demethylases, affirming the dynamic nature of histone modifications. This review highlights recent progress in plant epigenetic research, focusing on the H3K27me3 demethylases.