The extended AT-hook is a novel RNA binding motif.

The AT-hook has been defined as a DNA binding peptide motif that contains a glycine-arginine-proline (G-R-P) tripeptide core flanked by basic amino acids. Recent reports documented variations in the sequence of AT-hooks and revealed RNA binding activity of some canonical AT-hooks, suggesting a higher structural and functional variability of this protein domain than previously anticipated. Here we describe the discovery and characterization of the extended AT-hook peptide motif (eAT-hook), in which basic amino acids appear symmetrical mainly at a distance of 12-15 amino acids from the G-R-P core. We identified 80 human and 60 mouse eAT-hook proteins and biochemically characterized the eAT-hooks of Tip5/BAZ2A, PTOV1 and GPBP1. Microscale thermophoresis and electrophoretic mobility shift assays reveal the nucleic acid binding features of this peptide motif, and show that eAT-hooks bind RNA with one order of magnitude higher affinity than DNA. In addition, cellular localization studies suggest a role for the N-terminal eAT-hook of PTOV1 in nucleocytoplasmic shuttling. In summary, our findings classify the eAT-hook as a novel nucleic acid binding motif, which potentially mediates various RNA-dependent cellular processes.

Developmental regulation of N-terminal H2B methylation in Drosophila melanogaster.

Histone post-translational modifications play an important role in regulating chromatin structure and gene expression in vivo. Extensive studies investigated the post-translational modifications of the core histones H3 and H4 or the linker histone H1. Much less is known on the regulation of H2A and H2B modifications. Here, we show that a major modification of H2B in Drosophila melanogaster is the methylation of the N-terminal proline, which increases during fly development. Experiments performed in cultured cells revealed higher levels of H2B methylation when cells are dense, regardless of their cell cycle distribution. We identified dNTMT (CG1675) as the enzyme responsible for H2B methylation. We also found that the level of N-terminal methylation is regulated by dART8, an arginine methyltransferase that physically interacts with dNTMT and asymmetrically methylates H3R2. Our results demonstrate the existence of a complex containing two methyltransferases enzymes, which negatively influence each other's activity.

Analysis of histone modifications by mass spectrometry.

Histone N-termini undergo diverse post-translational modifications that significantly extend the information potential of the genetic code. Moreover, they appear to mark specific chromatin regions, modulating epigenetic control, lineage commitment, and overall function of chromosomes. It is widely accepted that histone modifications affect chromatin function, but the exact mechanisms of how modifications on histone tails and specific combinations of modifications are generated, and how they cross-talk with one another, is still enigmatic. Mass spectrometry is ideal for the analysis of histone modifications and is becoming the gold standard for histone post-translational modification analysis since it allows the quantification of modifications and combinations. This unit describes how high-resolution mass spectrometry can be used to study histone post-translational modifications.

Fine mapping of posttranslational modifications of the linker histone H1 from Drosophila melanogaster.

The linker histone H1 binds to the DNA in between adjacent nucleosomes and contributes to chromatin organization and transcriptional control. It is known that H1 carries diverse posttranslational modifications (PTMs), including phosphorylation, lysine methylation and ADP-ribosylation. Their biological functions, however, remain largely unclear. This is in part due to the fact that most of the studies have been performed in organisms that have several H1 variants, which complicates the analyses. We have chosen Drosophila melanogaster, a model organism, which has a single H1 variant, to approach the study of the role of H1 PTMs during embryonic development. Mass spectrometry mapping of the entire sequence of the protein showed phosphorylation only in the ten N-terminal amino acids, mostly at S10. For the first time, changes in the PTMs of a linker H1 during the development of a multicellular organism are reported. The abundance of H1 monophosphorylated at S10 decreases as the embryos age, which suggests that this PTM is related to cell cycle progression and/or cell differentiation. Additionally, we have found a polymorphism in the protein sequence that can be mistaken with lysine methylation if the analysis is not rigorous.

Epigenetic disruption of ribosomal RNA genes and nucleolar architecture in DNA methyltransferase 1 (Dnmt1) deficient cells.

The nucleolus is the site of ribosome synthesis in the nucleus, whose integrity is essential. Epigenetic mechanisms are thought to regulate the activity of the ribosomal RNA (rRNA) gene copies, which are part of the nucleolus. Here we show that human cells lacking DNA methyltransferase 1 (Dnmt1), but not Dnmt33b, have a loss of DNA methylation and an increase in the acetylation level of lysine 16 histone H4 at the rRNA genes. Interestingly, we observed that SirT1, a NAD+-dependent histone deacetylase with a preference for lysine 16 H4, interacts with Dnmt1; and SirT1 recruitment to the rRNA genes is abrogated in Dnmt1 knockout cells. The DNA methylation and chromatin changes at ribosomal DNA observed are associated with a structurally disorganized nucleolus, which is fragmented into small nuclear masses. Prominent nucleolar proteins, such as Fibrillarin and Ki-67, and the rRNA genes are scattered throughout the nucleus in Dnmt1 deficient cells. These findings suggest a role for Dnmt1 as an epigenetic caretaker for the maintenance of nucleolar structure.

Biomarker discovery from body fluids using mass spectrometry.

Systems analysis of body fluids by mass spectrometry (MS) is an upcoming field of biomarker research. This approach is extremely attractive because it does not require biomarker candidates and the sample preparation is simple. However, during the development of the technique strong critical comments were made on the poor reproducibility, the special characteristics of blood as a source of peptides and on the frequent non-adequate statistical analysis of the data. Here we discuss the efforts made in the last few years to develop suitable protocols, which could lead to biomarker discovery from body fluids by mass spectrometry. Our review focuses on the systems analysis of non-digested blood serum or plasma samples by MALDI-TOF and SELDI-TOF.

The analysis of histone modifications.

The biological function of many proteins is often regulated through posttranslational modifications (PTMs). Frequently different modifications influence each other and lead to an intricate network of interdependent modification patterns that affect protein-protein interactions, enzymatic activities and sub-cellular localizations. One of the best-studied class of proteins that is affected by PTMs and combinations thereof are the histone molecules. Histones are very abundant, small basic proteins that package DNA in the eukaryotic nucleus to form chromatin. The four core-histones are densely modified within their first 20-40 N-terminal amino acids, which are highly evolutionary conserved despite playing no structural role. The modifications are thought to constitute a histone code that is used by the cell to encrypt various chromatin conformations and gene expression states. The analysis of modified histones can be used as a model to dissect complex modification patterns and to investigate their molecular functions. Here we review techniques that have been used to decipher complex histone modification patterns and discuss the implication of these findings for chromatin structure and function.

Release of hypoacetylated and trimethylated histone H4 is an epigenetic marker of early apoptosis.

Nuclear events such as chromatin condensation, DNA cleavage at internucleosomal sites, and histone release from chromatin are recognized as hallmarks of apoptosis. However, there is no complete understanding of the molecular events underlying these changes. It is likely that epigenetic changes such as DNA methylation and histone modifications that are involved in chromatin dynamics and structure are also involved in the nuclear events described. In this report we have shown that apoptosis is associated with global DNA hypomethylation and histone deacetylation events in leukemia cells. Most importantly, we have observed a particular epigenetic signature for early apoptosis defined by a release of hypoacetylated and trimethylated histone H4 and internucleosomal fragmented DNA that is hypermethylated and originates from perinuclear heterochromatin. These findings provide one of the first links between apoptotic nuclear events and epigenetic markers.

Loss of acetylation at Lys16 and trimethylation at Lys20 of histone H4 is a common hallmark of human cancer.

CpG island hypermethylation and global genomic hypomethylation are common epigenetic features of cancer cells. Less attention has been focused on histone modifications in cancer cells. We characterized post-translational modifications to histone H4 in a comprehensive panel of normal tissues, cancer cell lines and primary tumors. Using immunodetection, high-performance capillary electrophoresis and mass spectrometry, we found that cancer cells had a loss of monoacetylated and trimethylated forms of histone H4. These changes appeared early and accumulated during the tumorigenic process, as we showed in a mouse model of multistage skin carcinogenesis. The losses occurred predominantly at the acetylated Lys16 and trimethylated Lys20 residues of histone H4 and were associated with the hypomethylation of DNA repetitive sequences, a well-known characteristic of cancer cells. Our data suggest that the global loss of monoacetylation and trimethylation of histone H4 is a common hallmark of human tumor cells.

Histone deacetylase inhibitors: understanding a new wave of anticancer agents.

Cancer is as much an epigenetic disease as it is a genetic and cytogenetic disease. The discovery that drastic changes in DNA methylation and histone modifications are commonly found in human tumors has inspired various laboratories and pharmaceutical companies to develop and study epigenetic drugs. One of the most promising groups of agents is the inhibitors of histone deacetylases (HDACs), which have different biochemical and biologic properties but have a single common activity: induction of acetylation in histones, the key proteins in nucleosome and chromatin structure. One of the main mechanisms of action of HDAC inhibitors is the transcriptional reactivation of dormant tumor-suppressor genes, such as p21WAF1. However, their pleiotropic nature leaves open the possibility that their well-known differentiation, cell-cycle arrest and apoptotic properties are also involved in other functions associated with HDAC inhibition. Many phase I clinical trials indicate that HDAC inhibitors appear to be well-tolerated drugs. Thus, the field is ready for rigorous biologic and clinical scrutiny to validate the therapeutic potential of these drugs. Our current data indicate that the use of HDAC inhibitors, probably in association with classical chemotherapy drugs or in combination with DNA-demethylating agents, could be promising for cancer patients.

Human DNA methyltransferase 1 is required for maintenance of the histone H3 modification pattern.

DNA methyltransferase 1 (DNMT1) plays an essential role in murine development and is thought to be the enzyme primarily responsible for maintenance of the global methylation status of genomic DNA. However, loss of DNMT1 in human cancer cells affects only the methylation status of a limited number of pericentromeric sequences. Here we show that human cancer cells lacking DNMT1 display at least two important differences with respect to wild type cells: a profound disorganization of nuclear architecture, and an altered pattern of histone H3 modification that results in an increase in the acetylation and a decrease in the dimethylation and trimethylation of lysine 9. Additionally, this phenotype is associated with a loss of interaction of histone deacetylases (HDACs) and HP1 (heterochromatin protein 1) with histone H3 and pericentromeric repetitive sequences (satellite 2). Our data indicate that DNMT1 activity, via maintenance of the appropriate histone H3 modifications, contributes to the preservation of the correct organization of large heterochromatic regions.

DNA methylation polymorphisms precede any histological sign of atherosclerosis in mice lacking apolipoprotein E.

The present work investigates the occurrence and significance of aberrant DNA methylation patterns during early stages of atherosclerosis. To this end, we asked whether the genetically atherosclerosis-prone APOE-null mice show any changes in DNA methylation patterns before the appearance of histologically detectable vascular lesion. We exploited a combination of various techniques: DNA fingerprinting, in vitro methyl-accepting assay, 5-methylcytosine quantitation, histone post-translational modification analysis, Southern blotting, and PCR. Our results show that alterations in DNA methylation profiles, including both hyper- and hypomethylation, were present in aortas and PBMC of 4-week-old mutant mice with no detectable atherosclerotic lesion. Sequencing and expression analysis of 60 leukocytic polymorphisms revealed that epigenetic changes involve transcribed genic sequences, as well as repeated interspersed elements. Furthermore, we showed for the first time that atherogenic lipoproteins promote global DNA hypermethylation in a human monocyte cell line. Taken together, our results unequivocally show that alterations in DNA methylation profiles are early markers of atherosclerosis in a mouse model and may play a causative role in atherogenesis.

Procaine is a DNA-demethylating agent with growth-inhibitory effects in human cancer cells.

Methylation-associated silencing of tumor suppressor genes is recognized as being a molecular hallmark of human cancer. Unlike genetic alterations, changes in DNA methylation are potentially reversible. This possibility has attracted considerable attention from a therapeutics standpoint. Nucleoside-analogue inhibitors of DNA methyltransferases, such as 5-aza-2'-deoxycytidine, are able to demethylate DNA and restore silenced gene expression. Unfortunately, the clinical utility of these compounds has not yet been fully realized, mainly because of their side effects. A few non-nucleoside inhibitors of DNA methyltransferases have been reported, including the anti-arrhythmia drug procainamide. Following this need to find new demethylating agents, we have tested the potential use of procaine, an anesthetic drug related to procainamide. Using the MCF-7 breast cancer cell line, we have found that procaine is a DNA-demethylating agent that produces a 40% reduction in 5-methylcytosine DNA content as determined by high-performance capillary electrophoresis or total DNA enzyme digestion. Procaine can also demethylate densely hypermethylated CpG islands, such as those located in the promoter region of the RAR beta 2 gene, restoring gene expression of epigenetically silenced genes. This property may be explained by our finding that procaine binds to CpG-enriched DNA. Finally, procaine also has growth-inhibitory effects in these cancer cells, causing mitotic arrest. Thus, procaine is a promising candidate agent for future cancer therapies based on epigenetics.

DNA demethylating agents and chromatin-remodelling drugs: which, how and why?

DNA hypermethylation at the CpG dinucleotides clustered in "islands" in the promoter regions of genes causes transcriptional repression through the remodelling of chromatin. Aberrant methylation patterns of tumor suppressor genes and their subsequent silencing constitute a common feature of many cancers. Thus, the search for drugs that interfere in methylation-mediated gene repression has become one of the major goals in the design of cancer therapies. The major actors in the mammalian methylation system are DNA-methyltransferases (DNMTs), and methyl-CpG-binding proteins (MBDs), which recognize methylated cytosine and recruit repressor complexes, including histone deacetylases (HDACs). In this context, two major groups of drugs can be distinguished. The first one is constituted by substances that inhibit the action of DNMTs, either competing with cytosine or with S-adenosylmethionine (SAM, AdoMet) or acting over the DNMTs themselves. The second group involves compounds that inhibit subunits of the repressor complexes, such as HDACs. In this manuscript we review these two different groups of drugs, discussing their properties and the side effects that have been described (that occur by interference with other metabolic pathways). We also propose the logical pharmacological extension of these findings to design more specific and effective drugs for the prevention and treatment of human cancer.