Spatial organization of the eukaryotic genome and the action of epigenetic mechanisms

Genome activity in eukaryotic cells is regulated at different levels. Long-term activation and repression of gene expression is controlled by epigenetic mechanisms. The main feature of epigenetic mechanisms is that regulatory events, provided by these mechanisms, are preserved in a series of cellular generations upon mitotic division, i.e., in a certain sense are inherited. Most of the epigenetic mechanisms, known so far, act at the level of nucleosomes and the dynamics of nucleosomal fibre. The important signal elements of epigenetic system are DNA methylation, histone modifications, and the inclusion of noncanonical forms of the histones in nucleosomes. In the present study, we substantiate the statement that the large-scale spatial organization of the DNA in eukaryotic cell also plays an important role in the action of epigenetic mechanisms.     

The dynamics of the nucleosome: thermal effects, external forces and ATP

With nucleosomes being tightly associated with the majority of eukaryotic DNA, it is essential that mechanisms are in place that can move nucleosomes 'out of the way'. A focus of current research comprises chromatin remodeling complexes, which are ATP-consuming protein complexes that, for example, pull or push nucleosomes along DNA. The precise mechanisms used by those complexes are not yet understood. Hints for possible mechanisms might be found among the various spontaneous fluctuations that nucleosomes show in the absence of remodelers. Thermal fluctuations induce the partial unwrapping of DNA from the nucleosomes and introduce twist or loop defects in the wrapped DNA, leading to nucleosome sliding along DNA. In this minireview, we discuss nucleosome dynamics from two angles. First, we describe the dynamical modes of nucleosomes in the absence of remodelers that are experimentally fairly well characterized and theoretically understood. Then, we discuss remodelers and describe recent insights about the possible schemes that they might use.     

Nucleosome destabilization in the epigenetic regulation of gene expression

Assembly, mobilization and disassembly of nucleosomes can influence the regulation of gene expression and other processes that act on eukaryotic DNA. Distinct nucleosome-assembly pathways deposit dimeric subunits behind the replication fork or at sites of active processes that mobilize pre-existing nucleosomes. Replication-coupled nucleosome assembly appears to be the default process that maintains silent chromatin, counteracted by active processes that destabilize nucleosomes. Nucleosome stability is regulated by the combined effects of nucleosome-positioning sequences, histone chaperones, ATP-dependent nucleosome remodellers, post-translational modifications and histone variants. Recent studies suggest that histone turnover helps to maintain continuous access to sequence-specific DNA-binding proteins that regulate epigenetic inheritance, providing a dynamic alternative to histone-marking models for the propagation of active chromatin.     

Dynamic and reversibility of heterochromatic gene silencing in human disease

MOLECULAR MECHANISM OF DNA METH- YLATION REACTION Among all epigenetic mechanisms involved in gene expression regulation, DNA methylation has been the most widely studied subject. DNA methylation results from the transfer of a methyl group from a methyl d…     

Epigenetic regulation of transcription by RNA polymerase III

Chromatin participates actively in all DNA transactions and all phenomena directly under the influence of chromatin are explained by epigenetic mechanisms. The genes transcribed by RNA polymerase (pol) III are generally found in regions free of nucleosomes, the structural units of chromatin. Yet, histone modifications and positions of nucleosomes in the gene flanking regions have been reported to show direct correlation with activity status of these genes. Gene-specific as well as genome-wide studies have also revealed association of several epigenetic components with pol III-transcribed genes. This review presents a summary of the research in past many years, which have gathered enough evidence to conclude that pol III-transcribed genes are important components of an epigenome.     

Functions of chromatin remodeling factors in heterochromatin formation and maintenance

Heterochromatin is characteristically more compact than euchromatin in the eukaryotic genome. The establishment of heterochromatin is mediated by special histone modifications, recruitment and propagation of heterochromatin specific proteins, as well as formation of special primary and high order structures of chromatin. Chromatin remodeling factors are ATPases that can alter the conformation and/or positioning of nucleosomes along DNA in an ATP-dependent manner. There is increasing evidence implicating chromatin remodeling activities in heterochromatin in various organisms ranging from yeasts to humans. Chromatin remodeling factors play roles in the establishment, maintenance and epigenetic inheritance of heterochromatin, but the underlying molecular mechanisms have just begun to be investigated.     

Long-range correlations between DNA bending sites: relation to the structure and dynamics of nucleosomes

It has been established that the precise positioning of nucleosomes on genomic DNA can be achieved, at least for a minority of them, through sequence-dependent processes. However, to what extent DNA sequences play a role in the positioning of the major part of nucleosomes is still debated. The aim of the present study is to examine to what extent long-range correlations (LRC) are related to the presence of nucleosomes. Using the wavelet transform technique, we perform a comparative analysis of the DNA text and of the corresponding bending profiles generated with curvature tables based on nucleosome positioning data. The exploration of a number of eukaryotic and bacterial genomes through the optics of the so-called "wavelet transform microscope" reveals a characteristic scale of 100-200 bp that separates two regimes of different LRC. Here, we focus on the existence of LRC in the small-scale regime (10-200 bp) which are actually observed in eukaryotic genomes, in contrast to their absence in eubacterial genomes. Analysis of viral DNA genomes shows that, like their host's genomes, eukaryotic viruses present LRC but eubacterial viruses do not. There is one exception for genomes of poxviruses (Vaccinia and Melamoplus sanguinipes) which do not replicate in the cell nucleus and do not exhibit LRC. No small-scale LRC are detected in the genomes of all examined RNA viruses, with the exception of retroviruses. These results together with the observation of LRC between particular sequence motifs known to participate in the formation of nucleosomes (e.g. AA dinucleotides) strongly suggest that the 10-200 bp LRC are a signature of the sequence-dependence of nucleosome positioning. Finally, we discuss possible interpretations of these LRC in terms of the physical mechanisms that might govern the positioning and the dynamics of the nucleosomes along the DNA chain through cooperative processes.     

Nucleosome positioning in relation to nucleosome spacing and DNA sequence-specific binding of a protein

Nucleosome positioning is an important mechanism for the regulation of eukaryotic gene expression. Folding of the chromatin fiber can influence nucleosome positioning, whereas similar electrostatic mechanisms govern the nucleosome repeat length and chromatin fiber folding in vitro. The position of the nucleosomes is directed either by the DNA sequence or by the boundaries created due to the binding of certain trans-acting factors to their target sites in the DNA. Increasing ionic strength results in an increase in nucleosome spacing on the chromatin assembled by the S-190 extract of Drosophila embryos. In this study, a mutant lac repressor protein R3 was used to find the mechanisms of nucleosome positioning on a plasmid with three R3-binding sites. With increasing ionic strength in the presence of R3, the number of positioned nucleosomes in the chromatin decreased, whereas the internucleosomal spacings of the positioned nucleosomes in a single register did not change. The number of the positioned nucleosomes in the chromatin assembled in vitro over different plasmid DNAs with 1-3 lac operators changed with the relative position and number of the R3-binding sites. We found that in the presence of R3, nucleosomes were positioned in the salt gradient method of the chromatin assembly, even in the absence of a nucleosome-positioning sequence. Our results show that nucleosome-positioning mechanisms are dominant, as the nucleosomes can be positioned even in the absence of regular spacing mechanisms. The protein-generated boundaries are more effective when more than one binding site is present with a minimum distance of approximately 165 bp, greater than the nucleosome core DNA length, between them.     

DNA甲基化与植物抗逆性研究进展

DNA甲基化是真核细胞基因组重要修饰方式之一.DNA甲基化通过与转录因子相互作用或通过改变染色质结构来影响基因的表达,从表观遗传水平对生物遗传信息进行调节,在生长发育过程中起着重要的作用,而且植物DNA甲基化还参与了环境胁迫下的基因表达调控过程.本文对植物DNA甲基化的产生机制、功能,以及DNA甲基化在植物应对逆境胁迫中的作用进行综述,以更好地理解植物DNA甲基化及其对环境胁迫的响应,为植物抗逆性研究及作物遗传改良提供理论参照.     

The inheritance of histone modifications depends upon the location in the chromosome in Saccharomyces cerevisiae

Histone modifications are important epigenetic features of chromatin that must be replicated faithfully. However, the molecular mechanisms required to duplicate and maintain histone modification patterns in chromatin remain to be determined. Here, we show that the introduction of histone modifications into newly deposited nucleosomes depends upon their location in the chromosome. In Saccharomyces cerevisiae, newly deposited nucleosomes consisting of newly synthesized histone H3-H4 tetramers are distributed throughout the entire chromosome. Methylation of lysine 4 on histone H3 (H3-K4), a hallmark of euchromatin, is introduced into these newly deposited nucleosomes, regardless of whether the neighboring preexisting nucleosomes harbor the K4 mutation in histone H3. Furthermore, if the heterochromatin-binding protein Sir3 is unavailable during DNA replication, histone H3-K4 methylation is introduced onto newly deposited nucleosomes in telomeric heterochromatin. Thus, a conservative distribution model most accurately explains the inheritance of histone modifications because the location of histones within euchromatin or heterochromatin determines which histone modifications are introduced.