A new regulator of the cell cycle: The PR-Set7 histone methyltransferase

The ability of eukaryotes to alter chromatin structure and function is modulated, in part, by histone-modifying enzymes and the post-translational modifications they create. One of these enzymes, PR-Set7/Set8/KMT5a, is the sole histone methyltransferase responsible for the monomethylation of histone H4 lysine 20 (H4K20me1) in higher eukaryotes. Both PR-Set7 and H4K20me1 were previously found to be tightly cell cycle regulated suggesting that they play an important, although unknown, role in cell cycle progression. Several recent reports reveal that PR-Set7 abundance is dynamically regulated during different cell cycle phases by distinct enzymes including cdk1/cyclinB, Cdc14, SCF^Skp2, CRL4^cdt2 and APC^cdh1. Importantly, these reports demonstrate that inappropriate levels of PR-Set7 result in profound cell cycle defects including the inability to initiate S phase, the re-replication of DNA and the improper timing of mitotic progression. Here, we summarize the significance of these new findings, raise some important questions that require further investigation and explore several possibilities of how PR-Set7 and methylated H4K20 may likely function as novel regulators of the cell cycle.Key words: PR-Set7, Set8, histone H4, methylation, ubiquitination, epigenetic, chromatin, SCF^Skp2, CRL4^cdt2, APC^cdh1, cdk1/cyclinB, Cdc14     

A new regulator of the cell cycle

The ability of eukaryotes to alter chromatin structure and function is modulated, in part, by histone-modifying enzymes and the post-translational modifications they create. One of these enzymes, PR-Set7/Set8/KMT5a, is the sole histone methyltransferase responsible for the monomethylation of histone H4 lysine 20 (H4K20me1) in higher eukaryotes. Both PR-Set7 and H4K20me1 were previously found to be tightly cell cycle regulated suggesting that they play an important, although unknown, role in cell cycle progression. Several recent reports reveal that PR-Set7 abundance is dynamically regulated during different cell cycle phases by distinct enzymes including cdk1/cyclinB, Cdc14, SCF^Skp2, CRL4^cdt2 and APC^cdh1. Importantly, these reports demonstrate that inappropriate levels of PR-Set7 result in profound cell cycle defects including the inability to initiate S phase, the re-replication of DNA and the improper timing of mitotic progression. Here, we summarize the significance of these new findings, raise some important questions that require further investigation and explore several possibilities of how PR-Set7 and methylated H4K20 may likely function as novel regulators of the cell cycle.     

Regulation of the histone H4 monomethylase PR-Set7 by CRL4(Cdt2)-mediated PCNA-dependent degradation during DNA damage

The histone methyltransferase PR-Set7/Set8 is the sole enzyme that catalyzes monomethylation of histone H4 at K20 (H4K20me1). Previous reports document disparate evidence regarding PR-Set7 expression during the cell cycle, the biological relevance of PR-Set7 interaction with PCNA, and its role in the cell. We find that PR-Set7 is indeed undetectable during S phase and instead is detected during late G2, mitosis, and early G1. PR-Set7 is transiently recruited to laser-induced DNA damage sites through its interaction with PCNA, after which 53BP1 is recruited dependent on PR-Set7 catalytic activity. During the DNA damage response, PR-Set7 interaction with PCNA through a specialized "PIP degron" domain targets it for PCNA-coupled CRL4(Cdt2)-dependent proteolysis. PR-Set7 mutant in its "PIP degron" is now detectable during S phase, during which the mutant protein accumulates. Outside the chromatin context, Skp2 promotes PR-Set7 degradation as well. These findings demonstrate a stringent spatiotemporal control of PR-Set7 that is essential for preserving the genomic integrity of mammalian cells.     

Catalytic function of the PR-Set7 histone H4 lysine 20 monomethyltransferase is essential for mitotic entry and genomic stability

Histone-modifying enzymes play a critical role in modulating chromatin dynamics. In this report we demonstrate that one of these enzymes, PR-Set7, and its corresponding histone modification, the monomethylation of histone H4 lysine 20 (H4K20), display a distinct cell cycle profile in mammalian cells: low at G1, increased during late S phase and G2, and maximal from prometaphase to anaphase. The lack of PR-Set7 and monomethylated H4K20 resulted in a number of aberrant phenotypes in several different mammalian cell types. These include the inability of cells to progress past G2, global chromosome condensation failure, aberrant centrosome amplification, and substantial DNA damage. By employing a catalytically dead dominant negative PR-Set7 mutant, we discovered that its mono-methyltransferase activity was required to prevent these phenotypes. Importantly, we demonstrate that all of the aberrant phenotypes associated with the loss of PR-Set7 enzymatic function occur independently of p53. Collectively, our findings demonstrate that PR-Set7 enzymatic activity is essential for mammalian cell cycle progression and for the maintenance of genomic stability, most likely by monomethylating histone H4K20. Our results predict that alterations of this pathway could result in gross chromosomal aberrations and aneuploidy.     

A switch in mitotic histone H4 lysine 20 methylation status is linked to M phase defects upon loss of HCF-1

The abundant chromatin-associated human factor HCF-1 is a heterodimeric complex of HCF-1N and HCF-1C subunits that are essential for two stages of the cell cycle. The HCF-1N subunit promotes G1 phase progression, whereas the HCF-1C subunit ensures proper cytokinesis at completion of M phase. How the HCF-1C subunit functions is unknown. Here, we show that HCF-1C subunit depletion causes extensive mitotic defects, including a switch from monomethyl to dimethyl lysine 20 of histone H4 (H4-K20) and defective chromosome alignment and segregation. Consistent with these activities, the HCF-1C subunit can associate with chromatin independently of the HCF-1N subunit and regulates the expression of the H4-K20 methyltransferase PR-Set7. Indeed, upregulation of PR-Set7 expression upon loss of HCF-1 leads to improper mitotic H4-K20 methylation and cytokinesis defects. These results establish the HCF-1C subunit as an important M phase regulator and suggest that H4-K20 methylation status contributes to chromosome behavior during mitosis and proper cytokinesis.     

Coupling mitosis to DNA replication: the emerging role of the histone H4-lysine 20 methyltransferase PR-Set7

To ensure accurate inheritance of genetic information through cell proliferation, chromosomes must be precisely copied only during S phase, and then correctly condensed and segregated during mitosis. Several new findings suggest that this tight coupling between DNA replication and mitosis is in part controlled by cell cycle regulated chromatin modifications, in particular due to the changing activity of lysine methyltransferase PR-Set7/SET8 that is responsible for the monomethylation of histone H4 at lysine 20. Cell cycle oscillation of PR-Set7 is orchestrated by ubiquitin-mediated proteolysis, and interference with this regulatory process leads to unscheduled licensing of replication origins and altered timing of mitotic chromosome compaction. This review provides an overview of how PR-Set7 regulates these two cell cycle events and highlights questions that remain to be addressed.     

Aberrant monomethylation of histone H4 lysine 20 activates the DNA damage checkpoint in Drosophila melanogaster

PR-Set7 is a histone methyltransferase that specifically monomethylates histone H4 lysine 20 (K20) and is essential for cell proliferation. Our results show that in PR-Set7 mutants, the DNA damage checkpoint is activated. This phenotype is manifested by reduction in both the mitotic and the S phase indexes, a delay in the progression through early mitosis, and strong reduction of cyclin B. Furthermore, in a double mutant of PR-Set7 and mei-41 (the fly ATR orthologue), the abnormalities of mitotic progression and the cyclin B protein level were rescued. PR-Set7 also showed a defect in chromosome condensation that was enhanced in the double mutant. We therefore propose that monomethylated H4K20 is involved in the maintenance of proper higher order structure of DNA and is consequently essential for chromosome condensation.     

Middle‐Down Characterization of the Cell Cycle Dependence of Histone H4 Posttranslational Modifications and Proteoforms

Post‐translational modifications (PTMs) of histones are important epigenetic regulatory mechanisms that are often dysregulated in cancer. We employ middle‐down proteomics to investigate the PTMs and proteoforms of histone H4 during cell cycle progression. We use pH gradient weak cation exchange‐hydrophilic interaction liquid chromatography (WCX‐HILIC) for on‐line liquid chromatography‐mass spectrometry analysis to separate and analyze the proteoforms of histone H4. This procedure provides enhanced separation of proteoforms, including positional isomers, and simplifies downstream data analysis. We use ultrahigh mass accuracy and resolution Fourier transform‐ion cyclotron resonance (FT‐ICR) mass spectrometer to unambiguously distinguish between acetylation and tri‐methylation (?m = 0.036 Da). In total, we identify and quantify 233 proteoforms of histone H4 in two breast cancer cell lines. We observe significant increases in S1 phosphorylation during mitosis, implicating an important role in mitotic chromatin condensation. A decrease of K20 unmodified proteoforms is observed as the cell cycle progresses, corresponding to an increase of K20 mono‐ and di‐methylation. Acetylation at K5, K8, K12, and K16 declines as cells traverse from S phase to mitosis, suggesting cell cycle–dependence and an important role during chromatin replication and condensation. These new insights into the epigenetics of the cell cycle may provide new diagnostic and prognostic biomarkers.     

Extent of histone modifications and H1 content during cell cycle progression in the presence of butyrate

The effects of butyrate upon the extents of phosphorylation of histones H1 and H1(0) during cell-cycle progression have been investigated. Chinese hamster (line CHO) cells were synchronized in early S phase and released into medium containing 0 or 15 mM butyrate to resume cell-cycle traverse into G1 of the next cell cycle. Cells were also mechanically selected from monolayer cultures grown in the presence of colcemid and 0 or 15 mM butyrate to obtain greater than 98% pure populations of metaphase cells. Although cell cycle progression is altered by butyrate, electrophoretic patterns of histones H1, H1(0), H3, and H4 indicate that butyrate has little, if any, effect on the extents of H1 and H1(0) phosphorylation during the cell cycle or the mitotic-specific phosphorylation of histone H3. Butyrate does, however, inhibit removal of extraordinary levels of histone H4 acetylation (hyperacetylation) during metaphase, and it appears to cause an increase in the content of H1(0) in chromatin during the S or G2 phases of the cell cycle.     

The Histone H4 Lysine 20 Monomethyl Mark,Set by PR-Set7 and Stabilized by L(3)mbt,Is Necessary for Proper Interphase Chromatin Organization

Drosophila PR-Set7 or SET8 is a histone methyltransferase that specifically monomethylates histone H4 lysine 20 (H4K20). L(3)MBT has been identified as a reader of methylated H4K20. It contains several conserved domains including three MBT repeats binding mono- and dimethylated H4K20 peptides. We find that the depletion of PR-Set7 blocks de novo H4K20me1 resulting in the immediate activation of the DNA damage checkpoint, an increase in the size of interphase nuclei, and drastic reduction of cell viability. L(3)mbt on the other hand stabilizes the monomethyl mark, as L(3)mbt-depleted S2 cells show a reduction of more than 60% of bulk monomethylated H4K20 (H4K20me1) while viability is barely affected. Ploidy and basic chromatin structure show only small changes in PR-Set7-depleted cells, but higher order interphase chromatin organization is significantly affected presumably resulting in the activation of the DNA damage checkpoint. In the absence of any other known functions of PR-Set7, the setting of the de novo monomethyl mark appears essential for cell viability in the presence or absence of the DNA damage checkpoint, but once newly assembled chromatin is established the monomethyl mark, protected by L(3)mbt, is dispensable.     

The PR-Set7 binding domain of Riz1 is required for the H4K20me1-H3K9me1 trans-tail ‘histone code’ and Riz1 tumor suppressor function

PR-Set7/Set8/KMT5a is the sole histone H4 lysine 20 monomethyltransferase (H4K20me1) in metazoans and is essential for proper cell division and genomic stability. We unexpectedly discovered that normal cellular levels of monomethylated histone H3 lysine 9 (H3K9me1) were also dependent on PR-Set7, but independent of its catalytic activity. This observation suggested that PR-Set7 interacts with an H3K9 monomethyltransferase to establish the previously reported H4K20me1-H3K9me1 trans-tail ‘histone code’. Here we show that PR-Set7 specifically and directly binds the C-terminus of the Riz1/PRDM2/KMT8 tumor suppressor and demonstrate that the N-terminal PR/SET domain of Riz1 preferentially monomethylates H3K9. The PR-Set7 binding domain was required for Riz1 nuclear localization and maintenance of the H4K20me1-H3K9me1 trans-tail ‘histone code’. Although Riz1 can function as a repressor, Riz1/H3K9me1 was dispensable for the repression of genes regulated by PR-Set7/H4K20me1. Frameshift mutations resulting in a truncated Riz1 incapable of binding PR-Set7 occur frequently in various aggressive cancers. In these cancer cells, expression of wild-type Riz1 restored tumor suppression by decreasing proliferation and increasing apoptosis. These phenotypes were not observed in cells expressing either the Riz1 PR/SET domain or PR-Set7 binding domain indicating that Riz1 methyltransferase activity and PR-Set7 binding domain are both essential for Riz1 tumor suppressor function.     

Analysis of dynamic changes in post-translational modifications of human histones during cell cycle by mass spectrometry

The N-terminal tails of the four core histones are subject to several types of covalent post-translational modifications that have specific roles in regulating chromatin structure and function. Here we present an extensive analysis of the core histone modifications occurring through the cell cycle. Our MS experiments characterized the modification patterns of histones from HeLa cells arrested in phase G1, S, and G2/M. For all core histones, the modifications in the G1 and S phases were largely identical but drastically different during mitosis. Modification changes between S and G2/M phases were quantified using the SILAC (stable isotope labeling by amino acids in cell culture) approach. Most striking was the mitotic phosphorylation on histone H3 and H4, whereas phosphorylation on H2A was constant during the cell cycle. A loss of acetylation was observed on all histones in G2/M-arrested cells. The pattern of cycle-dependent methylation was more complex: during G2/M, H3 Lys27 and Lys36 were decreased, whereas H4 Lys20 was increased. Our results show that mitosis was the period of the cell cycle during which many modifications exhibit dynamic changes.     

Differential acetylation of histone H4 lysine during development of in vitro fertilized,cloned and parthenogenetically activated bovine embryos

The oocyte is remarkable in its ability to remodel parental genomes following fertilization and to reprogram somatic nuclei after nuclear transfer (NT). To characterise the patterns of histone H4 acetylation and DNA methylation during development of bovine gametogenesis and embryogenesis, specific antibodies for histone H4 acetylated at lysine 5 (K5), K8, K12 and K16 residues and for methylated cytosine of CpG dinucleotides were used. Oocytes and sperm lacked the staining for histone acetylation, when DNA methylation staining was intense. In IVF zygotes, both pronuclei were transiently hyper-acetylated. However, the male pronucleus was faster in acquiring acetylated histones, and concurrently it was rapidly demethylated. Both pronuclei were equally acetylated during the S to G2-phase transition, while methylation staining was only still observed in the female pronucleus. In parthenogenetically activated oocytes, acetylation of the female pronucleus was enriched faster, while DNA remained methylated. A transient de-acetylation was observed in NT embryos reconstructed using a non-activated ooplast of a metaphase second arrested oocyte. Remarkably, the intensity of acetylation staining of most H4 lysine residues peaked at the 8-cell stage in IVF embryos, which coincided with zygotic genome activation and with lowest DNA methylation staining. At the blastocyst stage, trophectodermal cells of IVF and parthenogenetic embryos generally demonstrated more intense staining for most acetylated H4 lysine, whilst ICM cells stained very weakly. In contrast methylation of the DNA stained more intensely in ICM. NT blastocysts showed differential acetylation of blastomeres but not methylation. The inverse association of histone lysine acetylation and DNA methylation at different vital embryo stages suggests a mechanistically significant relationship. The complexities of these epigenetic interactions are discussed.     

Degrees make all the difference: The multifunctionality of histone H4 lysine 20 methylation

Residue and degree-specific methylation of histone lysines along with other epigenetic modifications organizes chromatin into distinct domains and regulates almost every aspect of DNA metabolism. Identification of histone methyltransferases and demethylases, as well as proteins that recognize methylated lysines, has clarified the role of each methylation event in regulating different biological pathways. Methylation of histone H4 lysine 20 (H4K20me) plays critical roles in diverse cellular processes such as gene expression, cell cycle progression and DNA damage repair, with each of the three degrees of methylation (mono- di- and tri-methylation) making a unique contribution. Here we discuss recent studies of H4K20me that have greatly improved our understanding of the regulation and function of this fascinating histone modification.     

Dynamic Acetylation of All Lysine 4–Methylated Histone H3 in the Mouse Nucleus: Analysis at c-fos and c-jun

A major focus of current research into gene induction relates to chromatin and nucleosomal regulation, especially the significance of multiple histone modifications such as phosphorylation, acetylation, and methylation during this process. We have discovered a novel physiological characteristic of all lysine 4 (K4)–methylated histone H3 in the mouse nucleus, distinguishing it from lysine 9–methylated H3. K4-methylated histone H3 is subject to continuous dynamic turnover of acetylation, whereas lysine 9–methylated H3 is not. We have previously reported dynamic histone H3 phosphorylation and acetylation as a key characteristic of the inducible proto-oncogenes c-fos and c-jun. We show here that dynamically acetylated histone H3 at these genes is also K4-methylated. Although all three modifications are proven to co-exist on the same nucleosome at these genes, phosphorylation and acetylation appear transiently during gene induction, whereas K4 methylation remains detectable throughout this process. Finally, we address the functional significance of the turnover of histone acetylation on the process of gene induction. We find that inhibition of turnover, despite causing enhanced histone acetylation at these genes, produces immediate inhibition of gene induction. These data show that all K4-methylated histone H3 is subject to the continuous action of HATs and HDACs, and indicates that at c-fos and c-jun, contrary to the predominant model, turnover and not stably enhanced acetylation is relevant for efficient gene induction.