Poly-ADP-Ribose (PAR) as an epigenetic flag

Epigenetics is the study of hereditable chromatin modifications, such as DNA methylation, histone modifications, and nucleosome-remodelling, which occur without alterations to the DNA sequence. The establishment of different epigenetic states in eukaryotes depends on regulatory mechanisms that induce structural changes in chromatin in response to environmental and cellular cues. Two classes of enzymes modulate chromatin accessibility: chromatin-covalent modifiers and ATP-dependent chromatin remodelling complexes. The first class of enzymes catalyzes covalent modifications of DNA as well as the amino- and carboxy-terminal tails of histones, while the second uses the energy of ATP hydrolysis to reposition nucleosomes along the chromatin fibers or to incorporate histone variants. Thus, epigenetic modifications are reversible nuclear reactions. In the last decade, many studies have strongly indicated that alterations in epigenetic modifications may contribute to the onset and progression of a variety of human diseases such as cancer. Therefore, the enzymes responsible for these chromatin changes are becoming attractive therapeutic targets.     

Structure and activity of enzymes that remove histone modifications

The post-translational modification of histones plays an important role in chromatin regulation, a process that insures the fidelity of gene expression and other DNA transactions. Equally important as the enzymes that generate these modifications are the enzymes that remove them. Recent studies have identified some of the enzymes that remove histone modifications and have characterized their activities. In addition, structural and biochemical studies of these enzymes have focused on the histone lysine deacetylases HDAC8 and sirtuins, and on the arginine and lysine demethylases PAD and BHC110/LSD1, respectively. These new findings may be used as a context to present new information that contributes to our understanding of chromatin regulation, and to pose remaining questions pertaining to the activities of these enzymes and the roles they play in chromatin regulation.     

Dynamic chromatin: concerted nucleosome remodelling and acetylation

The flexibility of chromatin that enables translation of environmental cues into changes in genome utilisation, relies on a battery of enzymes able to modulate chromatin structure in a highly targeted and regulated manner. The most dynamic structural changes are brought about by two kinds of enzymes with different functional principles. Changes in the acetylation status of histones modulate the folding of the nucleosomal fibre. The histone-DNA interactions that define the nucleosome itself can be disrupted by ATP-dependent remodelling factors. This review focuses on recent developments that illustrate various strategies for integrating these disparate activities into complex regulatory schemes. Synergies may be brought about by consecutive or parallel action during the stepwise process of chromatin opening or closing. Tight co-ordination may be achieved by direct interaction of (de-)acetylation enzymes and remodelling ATPases or even permanent residence within the same multi-enzyme complex. The fact that remodelling ATPases can be acetylated by histone acetyltransferases themselves suggests exciting possibilities for the co-ordinate modulation of chromatin structure and remodelling enzymes.     

Relationship of ultraviolet light-induced DNA-protein cross-linkage to chromatin structure

The production of banding patterns in metaphase chromosomes by restriction enzymes is inhibited by ultraviolet (UV) irradiation. Irradiation of fixed chromatin produces a 15-fold decrease in DNA extraction by restriction enzymes in comparison with that observed by irradiation before fixation. Alcohol-acid fixation of chromatin produces two major changes, the extraction of histones and dehydration. The effect of UV light is probably the result of a net increase in the yield of DNA-protein cross-links at comparable fluences of UV light and of the stabilization of the structural changes in the fixed chromatin fibril induced by the photoadducts. The X-irradiation of cells before fixation, as well as the rehydration of fixed chromatin, increases the extraction of DNA from fixed chromatin irradiated with UV light to levels similar to or even higher than those obtained with living cells. The effect of UV light before and after fixation on the extraction of DNA by restriction enzymes and proteinase K can be related to changes in chromatin structure and DNA conformation.     

Global role for chromatin remodeling enzymes in mitotic gene expression

Regulation of eukaryotic gene expression requires ATP-dependent chromatin remodeling enzymes, such as SWI/SNF, and histone acetyltransferases, such as Gcn5p. Here we show that SWI/SNF remodeling controls recruitment of Gcn5p HAT activity to many genes in late mitosis and that these chromatin remodeling enzymes play a role in regulating mitotic exit. In contrast, interphase expression of GAL1, HIS3, PHO5, and PHO8 is accompanied by SWI/SNF-independent recruitment of Gcn5p HAT activity. Surprisingly, prearresting cells in late mitosis imposes a requirement for SWI/SNF in recruiting Gcn5p HAT activity to the GAL1 promoter, and GAL1 expression also becomes dependent on both chromatin remodeling enzymes. We propose that SWI/SNF and Gcn5p are globally required for mitotic gene expression due to the condensed state of mitotic chromatin.     

The Role of Chromatin Modifications in Progression through Mouse Meiotic Prophase

Meiosis is a key event in gametogenesis that generates new combinations of genetic information and is required to reduce the chromosome content of the gametes.Meiotic chromosomes undergo a number of specialised events during prophase to allow meiotic recombination,homologous chromosome synapsis and reductional chromosome segregation to occur.In mammalian cells,DNA physically associates with histones to form chromatin,which can be modified by methylation,phosphorylation,ubiquitination and acetylation to help regulate higher order chromatin structure,gene expression,and chromosome organisation.Recent studies have identified some of the enzymes responsible for generating chromatin modifications in meiotic mammalian cells,and shown that these chromatin modifying enzymes are required for key meiosis-specific events that occur during meiotic prophase.This review will discuss the role of chromatin modifications in meiotic recombination,homologous chromosome synapsis and regulation of meiotic gene expression in mammals.     

Functional delineation of three groups of the ATP-dependent family of chromatin remodeling enzymes

ATP-dependent chromatin remodeling enzymes antagonize the inhibitory effects of chromatin. We compare six different remodeling complexes: ySWI/SNF, yRSC, hSWI/SNF, xMi-2, dCHRAC, and dNURF. We find that each complex uses similar amounts of ATP to remodel nucleosomal arrays at nearly identical rates. We also perform assays with arrays reconstituted with hyperacetylated or trypsinized histones and isolated histone (H3/H4)(2) tetramers. The results define three groups of the ATP-dependent family of remodeling enzymes. In addition we investigate the ability of an acidic activator to recruit remodeling complexes to nucleosomal arrays. We propose that ATP-dependent chromatin remodeling enzymes share a common reaction mechanism and that a key distinction between complexes is in their mode of regulation or recruitment.     

Histone lysine demethylases in Drosophila melanogaster

Epigenetic regulation of chromatin structure is a fundamental process for eukaryotes. Regulators include DNA methylation, microRNAs and chromatin modifications. Within the chromatin modifiers, one class of enzymes that can functionally bind and modify chromatin, through the removal of methyl marks, is the histone lysine demethylases. Here, we summarize the current findings of the 13 known histone lysine demethylases in Drosophila melanogaster, and discuss the critical role of these histone-modifying enzymes in the maintenance of genomic functions. Additionally, as histone demethylase dysregulation has been identified in cancer, we discuss the advantages for using Drosophila as a model system to study tumorigenesis.     

Histone lysine demethylases in Drosophila melanogaster

Epigenetic regulation of chromatin structure is a fundamental process for eukaryotes. Regulators include DNA methylation, microRNAs and chromatin modifications. Within the chromatin modifiers, one class of enzymes that can functionally bind and modify chromatin, through the removal of methyl marks, is the histone lysine demethylases. Here, we summarize the current findings of the 13 known histone lysine demethylases in Drosophila melanogaster, and discuss the critical role of these histone-modifying enzymes in the maintenance of genomic functions. Additionally, as histone demethylase dysregulation has been identified in cancer, we discuss the advantages for using Drosophila as a model system to study tumorigenesis.