K8 and K12 are biotinylated in human histone H4.

Folding of DNA into chromatin is mediated by binding to histones such as H4; association of DNA with histones is regulated by covalent histone modifications, e.g. acetylation, methylation, and biotinylation. We sought to identify amino-acid residues that are biotinylated in histone H4, and to determine whether acetylation and methylation of histones affect biotinylation. Synthetic peptides spanning fragments of human histone H4 were biotinylated enzymatically using biotinidase. Peptide-bound biotin was probed with streptavidin-peroxidase. Peptides based on the N-terminal sequence of histone H4 were effectively recognized by biotinidase as substrates for biotinylation; in contrast, peptides based on the C-terminal sequences were not biotinylated. Substitution of K8 or K12 with alanine or arginine decreased biotinylation, suggesting that these lysines are targets for biotinylation; K8 and K12 are also known targets for acetylation. Chemical acetylation or methylation of a given lysine decreased subsequent enzymatic biotinylation of neighboring lysines, consistent with cross-talk among histone modifications. Substitution of a given lysine (positive charge) with glutamate (negative charge) abolished biotinylation of neighboring lysines, providing evidence that the net charge of histones has a role in biotinylation. An antibody was generated that specifically recognized histone H4 biotinylated at K12. This antibody was used to detect biotinylated histone H4 in nuclear extracts from human cells. These studies suggest that K8 and K12 in histone H4 are targets for biotinylation, that acetylation and biotinylation compete for the same binding sites, and that acetylation and methylation of histones affect biotinylation of neighboring lysines.     

Lysine residues in N-terminal and C-terminal regions of human histone H2A are targets for biotinylation by biotinidase

In eukaryotic cell nuclei, DNA associates with the core histones H2A, H2B, H3 and H4 to form nucleosomal core particles. DNA binding to histones is regulated by posttranslational modifications of N-terminal tails (e.g., acetylation and methylation of histones). These modifications play important roles in the epigenetic control of chromatin structure. Recently, evidence that biotinidase and holocarboxylase synthetase (HCS) catalyze the covalent binding of biotin to histones has been provided. The primary aim of this study was to identify biotinylation sites in histone H2A and its variant H2AX. Secondary aims were to determine whether acetylation and methylation of histone H2A affect subsequent biotinylation and whether biotinidase and HCS localize to the nucleus in human cells. Biotinylation sites were identified using synthetic peptides as substrates for biotinidase. These studies provided evidence that K9 and K13 in the N-terminus of human histones H2A and H2AX are targets for biotinylation and that K125, K127 and K129 in the C-terminus of histone H2A are targets for biotinylation. Biotinylation of lysine residues was decreased by acetylation of adjacent lysines but was increased by dimethylation of adjacent arginines. The existence of biotinylated histone H2A in vivo was confirmed by using modification-specific antibodies. Antibodies to biotinidase and HCS localized primarily to the nuclear compartment, consistent with a role for these enzymes in regulating chromatin structure. Collectively, these studies have identified five novel biotinylation sites in human histones; histone H2A is unique among histones in that its biotinylation sites include amino acid residues from the C-terminus.     

Prokaryotic BirA ligase biotinylates K4, K9, K18 and K23 in histone H3

BirA ligase is a prokaryotic ortholog of holocarboxylase synthetase (HCS) that can biotinylate proteins. This study tested the hypothesis that BirA ligase catalyzes the biotinylation of eukaryotic histones. If so, this would mean that recombinant BirA ligase is a useful surrogate for HCS in studies of histone biotinylation. The biological activity of recombinant BirA ligase was confirmed by enzymatic biotinylation of p67. In particular, it was found that BirA ligase biotinylated both calf thymus histone H1 and human bulk histone extracts. Incubation of recombinant BirA ligase with H3-based synthetic peptides showed that lysines 4, 9, 18, and 23 in histone H3 are the targets for the biotinylation by BirA ligase. Modification of the peptides (e.g., serine phosphorylation) affected the subsequent biotinylation by BirA ligase, suggesting crosstalk between modifications. In conclusion, this study suggests that prokaryotic BirA ligase is a promiscuous enzyme and biotinylates eukaryotic histones. Moreover the biotinylation of histones by BirA ligase is consistent with the proposed role of human HCS in chromatin.     

Holocarboxylase synthetase is a chromatin protein and interacts directly with histone H3 to mediate biotinylation of K9 and K18

Holocarboxylase synthetase (HCS) mediates the binding of biotin to lysine (K) residues in histones H2A, H3 and H4; HCS knockdown disturbs gene regulation and decreases stress resistance and lifespan in eukaryotes. We tested the hypothesis that HCS interacts physically with histone H3 for subsequent biotinylation. Co-immunoprecipitation experiments were conducted and provided evidence that HCS co-localizes with histone H3 in human cells; physical interactions between HCS and H3 were confirmed using limited proteolysis assays. Yeast two-hybrid (Y2H) studies revealed that the N-terminal and C-terminal domains in HCS participate in H3 binding. Recombinant human HCS was produced and exhibited biological activity, as evidenced by biotinylation of its known substrate, recombinant p67. Recombinant histone H3.2 and synthetic H3-based peptides were also good targets for biotinylation by recombinant HCS (rHCS) in vitro, based on tracing histone-bound biotin with [³H]biotin, streptavidin and anti-biotin antibody. Biotinylation site-specific antibodies were generated and revealed that both K9 and K18 in H3 were biotinylated by HCS. Collectively, these studies provide conclusive evidence that HCS interacts directly with histone H3, causing biotinylation of K9 and K18. We speculate that the targeting of HCS to distinct regions in human chromatin is mediated by DNA sequence, biotin, RNA, epigenetic marks or chromatin proteins.     

Artifactual detection of biotin on histones by streptavidin

Biotinylation is a recent addition to the list of reported posttranslational modifications made to histones. Holocarboxylase synthetase (HCS) and biotinidase have been implicated as biotinylating enzymes. However, the details of the mechanism and the regulation of biotin transfer on and off histones remains unclear. Here we report that in a cell culture system low biotin availability reduces biotinylation of carboxylases, yet apparent biotinylation of histones is unaffected. This is despite biotin depletion having detrimental effects on cell viability and proliferation. Further analysis of the widely used method for detecting biotin on histones, streptavidin blotting, revealed that streptavidin interacts with histones independently of biotin binding. Preincubation of streptavidin with free biotin reduced binding to biotinylated carboxylases but did not block binding to histones. To investigate biotinylation of histones using an alternative detection method independent of streptavidin, incorporation of 14C biotin into biotinylated proteins was analyzed. Radiolabeled biotin was readily detectable on carboxylases but not on histones, implying very low levels of biotin in the nucleus attached to histone proteins (< 0.03% biotinylation). In conclusion, we would caution against the use of streptavidin for investigating histone biotinylation.     

Biotinylation of histones in human cells. Effects of cell proliferation.

An enzymatic mechanism has been proposed by which biotinidase may catalyze biotinylation of histones. Here, human cells were found to covalently bind biotin to histones H1, H2A, H2B, H3, and H4. Cells respond to proliferation with increased biotinylation of histones; biotinylation increases early in the cell cycle and remains increased during the cycle. Notwithstanding the catalytic role of biotinidase in biotinylation of histones, mRNA encoding biotinidase and biotinidase activity did not parallel the increased biotinylation of histones in proliferating cells. Biotinylation of histones might be regulated by enzymes other than biotinidase or by the rate of histone debiotinylation.     

组蛋白的生物素酰化修饰

组蛋白修饰对基因表达的表观遗传学调控起着重要作用。组蛋白生物素酰化修饰是近年来新发现的一种组蛋白修饰,具有重要的生物学功能。有证据表明组蛋白生物素酰化在细胞增殖、DNA修复、维持基因组稳定等方面发挥作用。组蛋白的生物素酰化修饰是由羧化全酶合成酶与组蛋白直接相互作用的结果。本文主要介绍了组蛋白生物素酰化发现的过程,并对近年来在组蛋白生物素酰化催化机制和组蛋白生物素酰化功能方面的研究进展进行了综述,最后对组蛋白生物素酰化研究领域存在的问题进行了探讨。     

K12-biotinylated histone H4 is enriched in telomeric repeats from human lung IMR-90 fibroblasts

Covalent modifications of histones play a role in regulating telomere attrition and cellular senescence. Biotinylation of lysine (K) residues in histones, mediated by holocarboxylase synthetase (HCS), is a novel diet-dependent mechanism to regulate chromatin structure and gene expression. We have previously shown that biotinylation of K12 in histone H4 (H4K12bio) is a marker for heterochromatin and is enriched in pericentromeric alpha satellite repeats. Here, we hypothesized that H4K12bio is also enriched in telomeres. We used human IMR-90 lung fibroblasts and immortalized IMR-90 cells overexpressing human telomerase (hTERT) in order to examine histone biotinylation in young and senescent cells. Our studies suggest that one out of three histone H4 molecules in telomeres is biotinylated at K12 in hTERT cells. The abundance of H4K12bio in telomeres decreased by 42% during telomere attrition in senescent IMR-90 cells; overexpression of telomerase prevented the loss of H4K12bio. Possible confounders such as decreased expression of HCS and biotin transporters were formally excluded in this study. Collectively, these data suggest that H4K12bio is enriched in telomeric repeats and represents a novel epigenetic mark for cell senescence.     

Biotin requirements for DNA damage prevention

Biotin serves as a covalently bound coenzyme in five human carboxylases; biotin is also attached to histones H2A, H3, and H4, although the abundance of biotinylated histones is low. Biotinylation of both carboxylases and histones is catalyzed by holocarboxylase synthetase. Human biotin requirements are unknown. Recommendations for adequate intake of biotin are based on the typical intake of biotin in an apparently healthy population, which is only a crude estimate of the true intake due to analytical problems. Importantly, intake recommendations do not take into account possible effects of biotin deficiency on impairing genome stability. Recent studies suggest that biotin deficiency causes de-repression of long terminal repeats, thereby causing genome instability. While it was originally proposed that these effects are caused by loss of biotinylated histones, more recent evidence suggests a more immediate role of holocarboxylase synthetase in forming multiprotein complexes in chromatin that are important for gene repression. Holocarboxylase synthetase appears to interact physically with the methyl-CpG-binding domain protein 2 and, perhaps, histone methyl transferases, thereby creating epigenetic synergies between biotinylation and methylation events. These observations might offer a mechanistic explanation for some of the birth defects seen in biotin-deficient animal models.     

Symmetrical modification within a nucleosome is not required globally for histone lysine methylation

Two copies of each core histone exist in every nucleosome; however, it is not known whether both histones within a nucleosome are required to be symmetrically methylated at the same lysine residues. We report that for most lysine methylation states, wild-type histones paired with mutant, unmethylatable histones in mononucleosomes have comparable methylation levels to bulk histones. Our results indicate that symmetrical histone methylation is not required on a global scale. However, wild-type H4 histones paired with unmethylatable H4K20R histones showed reduced levels of H4K20me2 and H4K20me3, suggesting that some fractions of these modifications might exist symmetrically, and enzymes mediating these modifications might, to some extent, favour nucleosome substrates with premethylated H4K20.     

Distinctive core histone post-translational modification patterns in Arabidopsis thaliana

Post-translational modifications of histones play crucial roles in the genetic and epigenetic regulation of gene expression from chromatin. Studies in mammals and yeast have found conserved modifications at some residues of histones as well as non-conserved modifications at some other sites. Although plants have been excellent systems to study epigenetic regulation, and histone modifications are known to play critical roles, the histone modification sites and patterns in plants are poorly defined. In the present study we have used mass spectrometry in combination with high performance liquid chromatography (HPLC) separation and phospho-peptide enrichment to identify histone modification sites in the reference plant, Arabidopsis thaliana. We found not only modifications at many sites that are conserved in mammalian and yeast cells, but also modifications at many sites that are unique to plants. These unique modifications include H4 K20 acetylation (in contrast to H4 K20 methylation in non-plant systems), H2B K6, K11, K27 and K32 acetylation, S15 phosphorylation and K143 ubiquitination, and H2A K144 acetylation and S129, S141 and S145 phosphorylation, and H2A.X S138 phosphorylation. In addition, we found that lysine 79 of H3 which is highly conserved and modified by methylation and plays important roles in telomeric silencing in non-plant systems, is not modified in Arabidopsis. These results suggest distinctive histone modification patterns in plants and provide an invaluable foundation for future studies on histone modifications in plants.     

Phosphorylation of H3S10 blocks the access of H3K9 by specific antibodies and histone methyltransferase. Implication in regulating chromatin dynamics and epigenetic inheritance during mitosis

Post-translational modifications of histones play a critical role in regulating genome structures and integrity. We have focused on the regulatory relationship between covalent modifications of histone H3 lysine 9 (H3K9) and H3S10 during the cell cycle. Immunofluorescence microscopy revealed that H3S10 phosphorylation in HeLa, A549, and HCT116 cells was high during prophase, prometaphase, and metaphase, whereas H3K9 monomethylation (H3K9me1) and dimethylation (H3K9me2), but not H3K9 trimethylation (H3K9me3), were significantly suppressed. When H3S10 phosphorylation started to diminish during anaphase, H3K9me1 and H3K9me2 signals reemerged. Western blot analyses confirmed that mitotic histones, extracted in an SDS-containing buffer, had little H3K9me1 and H3K9me2 signals but abundant H3K9me3 signals. However, when mitotic histones were extracted in the same buffer without SDS, the difference in H3K9me1 and H3K9me2 signals between interphase and mitotic cells disappeared. Removal of H3S10 phosphorylation by pretreatment with lambda-phosphatase unmasked mitotic H3K9me1 and H3K9me2 signals detected by both fluorescence microscopy and Western blotting. Further, H3S10 phosphorylation completely blocked methylation of H3K9 but not demethylation of the same residue in vitro. Given that several conserved motifs consisting of a Lys residue immediately followed by a Ser residue are present in histone tails, our studies reveal a potential new mechanism by which phosphorylation not only regulates selective access of methylated lysines by cellular factors but also serves to preserve methylation patterns and epigenetic programs during cell division.     

Nucleosome-interacting proteins regulated by DNA and histone methylation

Modifications on histones or on DNA recruit proteins that regulate chromatin function. Here, we use nucleosomes methylated on DNA and on histone H3 in an affinity assay, in conjunction with a SILAC-based proteomic analysis, to identify "crosstalk" between these two distinct classes of modification. Our analysis reveals proteins whose binding to nucleosomes is regulated by methylation of CpGs, H3K4, H3K9, and H3K27 or a combination thereof. We identify the origin recognition complex (ORC), including LRWD1 as a subunit, to be a methylation-sensitive nucleosome interactor that is recruited cooperatively by DNA and histone methylation. Other interactors, such as the lysine demethylase Fbxl11/KDM2A, recognize nucleosomes methylated on histones, but their recruitment is disrupted by DNA methylation. These data establish SILAC nucleosome affinity purifications (SNAP) as a tool for studying the dynamics between different chromatin modifications and provide a modification binding "profile" for proteins regulated by DNA and histone methylation.     

Molecular implementation and physiological roles for histone H3 lysine 4 (H3K4) methylation

Chromosomal surfaces are ornamented with a variety of post-translational modifications of histones, which are required for the regulation of many of the DNA-templated processes. Such histone modifications include acetylation, sumoylation, phosphorylation, ubiquitination, and methylation. Histone modifications can either function by disrupting chromosomal contacts or by regulating non-histone protein interactions with chromatin. In this review, recent findings will be discussed regarding the regulation of the implementation and physiological significance for one such histone modification, histone H3 lysine 4 (H3K4) methylation by the yeast COMPASS and mammalian COMPASS-like complexes.