TET2 gene expression and 5-hydroxymethylcytosine level in multiple sclerosis peripheral blood cells.

Aberrant DNA methylation can lead to genome destabilization and to deregulated gene expression. Recently, 5-hydroxymethylcytosine (5hmC), derived from oxidation of 5-methylcytosine (5mC) by the Ten-Eleven Translocation (TET) enzymes, has been detected. 5hmC is now considered as a new epigenetic DNA modification with relevant roles in cell homeostasis regulating DNA demethylation and transcription. Our aim was to investigate possible changes in the DNA methylation/demethylation machinery in MS. We assessed the expression of enzymes involved in DNA methylation/demethylation in peripheral blood mononuclear cells (PBMCs) from 40 subjects with MS and 40 matched healthy controls. We performed also, DNA methylation analysis of specific promoters and analysis of global levels of 5mC and 5hmC. We show that TET2 and DNMT1 expression is significantly down-regulated in MS PBMCs and it is associated with aberrant methylation of their promoters. Furthermore, 5hmC is decreased in MS PBMCs, probably as a result of the diminished TET2 level.

Validation of suitable internal control genes for expression studies in aging.

Quantitative data from experiments of gene expression are often normalized through levels of housekeeping genes transcription by assuming that expression of these genes is highly uniform. This practice is being questioned as it becomes increasingly clear that the level of housekeeping genes expression may vary considerably in certain biological samples. To date, the validation of reference genes in aging has received little attention and suitable reference genes have not yet been defined. Our aim was to evaluate the expression stability of frequently used reference genes in human peripheral blood mononuclear cells with respect to aging. Using quantitative RT-PCR, we carried out an extensive evaluation of five housekeeping genes, i.e. 18s rRNA, ACTB, GAPDH, HPRT1 and GUSB, for stability of expression in samples from donors in the age range 35-74 years. The consistency in the expression stability was quantified on the basis of the coefficient of variation and two algorithms termed geNorm and NormFinder. Our results indicated GUSB be the most suitable transcript and 18s the least for accurate normalization in PBMCs. We also demonstrated that aging is a confounding factor with respect to stability of 18s, HPRT1 and ACTB expression, which were particularly prone to variability in aged donors.

CCCTC-binding factor: to loop or to bridge.

Eukaryotic genomes have complex spatial organization in the nucleus. The factors and the mechanisms involved in this organization remain an enigma. Among the many proteins implicated in such a role, the ubiquitous Zn-finger protein CTCF stands out. Here we summarize the evidence placing CTCF in the enviable position of a master organizer of the genome. CTCF can form loops in cis, and can bridge sequences located on different chromosomes in trans. The thousands of CTCF binding sites, identified in recent genome-wide localization studies, and their distribution along the genome further support a crucial role of CTCF as a chromatin organizer.

DNA methylation-dependent chromatin fiber compaction in vivo and in vitro: requirement for linker histone.

Dynamic alterations in chromatin structure mediated by postsynthetic histone modifications and DNA methylation constitute a major regulatory mechanism in DNA functioning. DNA methylation has been implicated in transcriptional silencing, in part by inducing chromatin condensation. To understand the methylation-dependent chromatin structure, we performed atomic force microscope (AFM) studies of fibers isolated from cultured cells containing normal or elevated levels of m5C. Chromatin fibers were reconstituted on control or methylated DNA templates in the presence or absence of linker histone. Visual inspection of AFM images, combined with quantitative analysis of fiber structural parameters, suggested that DNA methylation induced fiber compaction only in the presence of linker histones. This conclusion was further substantiated by biochemical results.

Differential expression of class I HDACs: roles of cell density and cell cycle.

Enzymes which affect histone acetylation status have been shown to play an important role in determining transcriptional activity in chromatin through conformational modification of its structure. Since the timely presence of such enzymes may be of critical importance, our experiments were designed to determine whether the level of expression of HDAC1 is cell cycle dependent and/or affected by a high cell density. Our results show that in mouse fibroblasts the expression of mHDAC1 is neither affected by cell cycle phases nor by cell density. In contrast, the expression of several hHDACs including hHDAC1 were affected in a cell density dependent fashion in the human prostate adenocarcinoma cell line PC3, paralleling our previously published findings in the hepatocellular carcinoma derived cell line Hep3B. Differential recruitment of HDAC mRNAs suggests that these enzymes may play unique roles in different cell types and under different environmental conditions (i.e., exposure to various cell densities and cell-cell contacts). Our study has implications for the proposed use of HDAC inhibitors in the treatment of human malignancy, highlighting issues of drug action selectivity in tissues and potential secondary effects.

Linker histone binding and displacement: versatile mechanism for transcriptional regulation.

In recent years, the connection between chromatin structure and its transcriptional activity has attracted considerable experimental effort. The post-translational modifications to both the core histones and the linker histones are finely tuned through interactions with transcriptional regulators and change chromatin structure in a way to allow transcription to occur. Here we review evidence for the involvement of linker histones in transcriptional regulation and suggest a scenario in which the reversible and controllable binding/displacement of proteins of this class to the nucleosome entry/exit point determine the accessibility of the nucleosomal DNA to the transcriptional machinery.

In vitro induction of H1-H1 histone cross-linking by adenosine diphosphate-ribose polymers.

It is well-known that H1-H1 interactions are very important for the induction of 30 nm chromatin fiber and that, among all posttranslational modifications, poly(ADP-ribosyl)ation is one of those capable of modifying chromatin structure, mainly through H1 histone. As this protein can undergo both covalent and noncovalent modifications by poly(ADP-ribosyl)ation, our aim was to investigate whether and how ADP-ribose polymers, by themselves, are able to affect the formation of H1-H1 oligomers, which are normally present in a condensed chromatin structure. The results obtained in our in vitro experimental system indicate that ADP-ribose polymers are involved in chromatin decondensation. This conclusion was reached as the result of two different observations: (a) H1 histone molecules can be hosted in clusters on ADP-ribose polymers, as shown by their ability to be chemically cross-linked, and (b) H1 histone has a higher affinity for ADP-ribose polymers than for DNA; ADP-ribose polymers compete, in fact, with DNA for H1 histone binding.

Inhibition of poly(ADP-ribosyl)ation introduces an anomalous methylation pattern in transfected foreign DNA.

The aim of this paper is to verify whether the control played by poly(ADP-ribosyl)ation on genomic DNA methylation, and in particular on CpG islands, can also be seen on foreign DNA transfected in cells where inhibition of the poly(ADP-ribosyl)ation process was obtained by treating them with 2 mM 3-aminobenzamide for 24 h. The CpG island-like pVHCk plasmid containing the bacterial chloramphenicol acyltransferase (CAT) gene under the control of SV40 early promoter was transfected in L929 mouse fibroblast cells. The bisulfite reaction, which is capable of immortalizing the methylation state of cytosine on DNA, was performed before amplification of the plasmid DNA fragment, then used for sequence analysis. Our results have shown that 1) when transfected in control cells, the plasmid maintains its characteristic unmethylated pattern, whereas this pattern is lost when the plasmid is transfected in cells treated with 3-aminobenzamide; and 2) the presence of new methyl groups on plasmid DNA is paralleled by a decrease of CAT reporter gene expression. These data confirm that poly(ADP-ribosyl)ation is a process tightly involved in protecting genomic DNA from full methylation and suggest the use of 3-aminobenzamide as a possible experimental strategy to mime other conditions of DNA hypermethylation in cells.

Reduced levels of poly(ADP-ribosyl)ation result in chromatin compaction and hypermethylation as shown by cell-by-cell computer-assisted quantitative analysis.

The unmethylated status of the CpG islands is important for gene expression of correlated housekeeping genes since it is well known that their methylation inhibits transcription process. An interesting question that has been discussed but not solved is how the CpG islands maintain their characteristic unmethylated status even though they are rich in CpG dinucleotides. Our previous in vitro and in vivo research has shown that poly(ADP-ribosyl)ation is involved in protecting CpG dinucleotides from full methylation in genomic DNA and that a block of poly(ADP-ribosyl)ation is also involved in modifying the methylation pattern in the promoter region of Htf9 housekeeping gene. In this study we locked for cytological evidence that in the absence of an active poly(ADP-ribosyl)ation the DNA methylation pattern in L929 and NIH/3T3 mouse fibroblast cell lines is altered. For this purpose, differences in the methylation levels of interphase nuclei from control and treated cultures of two murine cell lines preincubated with 2 mM 3-aminobenzamide, an inhibitor of poly(ADP-ribosyl)ation, were measured in individual cells after indirect immunolabeling with anti-5MeC antibodies. The quantitative analysis allowed us to demonstrate that blocking of the poly(ADP-ribosyl)ation results in a higher number, size, and density of antibody binding regions in treated cells when compared to the controls. Analogously, sequential Giemsa staining and indirect immunolabeling of the same slides showed the heterochromatic regions colocalized with the extended methyl-rich domains.

Efficiency of expression of transfected genes depends on the cell cycle.

Lipofection, a lipid-mediated DNA transfection procedure, was used to transfect synchronized L929 mouse fibroblast cells with a reporter plasmid containing the bacterial chloramphenicol acetyltransferase gene. The efficiency of gene expression was investigated on transfection of cells at different stages of the cell cycle. Our data show that expression of the reporter gene was minimal when transfection was performed in G0-phase and parallel experimental data disproved the possibility that the reduced expression observed was due to differential uptake at different times in the cell cycle. Investigation into the condensation state of the plasmid has shown that the low chloramphenicol acetyltransferase gene expression could be a direct consequence of the packaging of the plasmid into condensed chromatin when transfection occurs in G0-phase. The inactivation of the reporter gene is not reversed by growth of the cells in high serum or by treatment with Trichostatin A, a specific inhibitor of histone deacetylase, suggesting that the inactive chromatin formed in G0-phase cells lacks associated histone acetylase activity. In contrast, the high activity seen when cells in S-phase are transfected is enhanced even further by treatment with Trichostatin A.

H1 histone as a trans-acting factor involved in protecting genomic DNA from full methylation.

This review aims to explain why H1 histone can be considered as a protein involved in protecting genomic DNA from full methylation. Some of our results indicated that, to explain the multiple roles in which H1 histone seems to be involved, it is important to consider that it is not a unique protein but a family of genetic somatic variants and that every one of them can be dynamically modified by different post-synthetic enzymatic modifications. Our data show that H1 histone plays an inhibitory effect on DNA methylation through its H1e variant and that poly(ADP-ribosyl)ation is a post-synthetic modification involved in this regulatory role. The idea that the poly(ADP-ribosyl)ated isoform of H1e could be present in decondensed chromatin structure, where the housekeeping genes are located, will be discussed.

The unmethylated state of CpG islands in mouse fibroblasts depends on the poly(ADP-ribosyl)ation process.

In vivo and in vitro experiments carried out on L929 mouse fibroblasts suggested that the poly(ADP-ribosyl) ation process acts somehow as a protecting agent against full methylation of CpG dinucleotides in genomic DNA. Since CpG islands, which are found almost exclusively at the 5'-end of housekeeping genes, are rich in CpG dinucleotides, which are the target of mammalian DNA methyltransferase, we examined the possibility that the poly(ADP-ribosyl)ation reaction is involved in maintaining the unmethylated state of these DNA sequences. Experiments were conducted by two different strategies, using either methylation-dependent restriction enzymes on purified genomic DNA or a sequence-dependent restriction enzyme on an aliquot of the same DNA, previously modified by a bisulfite reaction. With the methylation-dependent restriction enzymes, it was observed that the "HpaII tiny fragments" greatly decreased when the cells were preincubated with 3-aminobenzamide, a well known inhibitor of poly(ADP-ribose) polymerase. The other experimental approach allowed us to prove that, as a consequence of the inhibition of the poly(ADP-ribosyl)ation process, an anomalous methylation pattern could be evidenced in the CpG island of the promoter fragment of the Htf9 gene, amplified from DNA obtained from fibroblasts preincubated with 3-aminobenzamide. These data confirm the hypothesis that, at least for the Htf9 promoter region, an active poly(ADP-ribosyl)ation protects the unmethylated state of the CpG island.

Does poly(ADP-ribosyl)ation regulate the DNA methylation pattern?

The existence of a possible correlation between poly(ADP-ribosyl)ation and DNA methylation processes was investigated. In vivo and in vitro experiments were carried out on L929 mouse fibroblasts preincubated for 24 h with or without 3-aminobenzamide, a well-known inhibitor of poly(ADP-ribose) polymerase. Both experimental approaches evidenced a close relationship between these two important nuclear enzymatic mechanisms, suggesting that the poly(ADP-ribosyl)ated isoform of H1 histone and/or long and branched protein-free ADP-ribose polymers could act as protecting agents against full methylation of the CpG dinucleotides in genomic DNA.

H1-H1 cross-linking efficiency depends on genomic DNA methylation.

Oligonucleosomal DNA preparations from condensed-inactive chromatin were examined, before and after artificial methylation by bacterial SssI methylase, for their ability to allow cooperative H1-H1 interactions under conditions of different ionic strength. Our results support the conclusion that, within the highly methylated genomic DNA, there are some CpG's whose unmethylated state is critical for chromatin folding. Circular dichroism spectra indicate that artificial overmethylation of native oligonucleosomal DNA reduces its efficiency in inducing an ordered conformation of H1 histone. Temperature melting profiles confirm on the other hand that the native and the artificially overmethylated forms of oligonucleosomal DNA are both able to bind H1 histone.

Different effects of histone H1 on de novo DNA methylation in vitro depend on both the DNA base composition and the DNA methyltransferase.

We have characterized the inhibition exerted by histone H1 on the activity of human placenta DNA (cytosine-5-)-methyltransferase. Our experiments demonstrate that the extent of inhibition depends on the DNA base composition, AT-rich substrates being more severely affected than GC-rich substrates and CpG-rich islands. With bacterial SssI methylase, the effect is completely reversed since its activity on AT-rich substrates undergoes a 4-5-fold stimulation upon the addition of H1. Poly(L-lysine) mimicks H1 effects, suggesting an essential role of lysine residues in both the inhibitory and stimulatory effects of H1. By comparison of the different behaviors of the two enzymes, the inhibitory effect over the eukaryotic enzyme might be accounted for by hypothesizing a competition between minor groove-binding motifs (SPKK-like) present in placenta methylase as well as in histone H1.

Co-operative interactions of oligonucleosomal DNA with the H1e histone variant and its poly(ADP-ribosyl)ated isoform.

H1 histone somatic variants from L929 mouse fibroblasts were purified by reverse-phase HPLC. We analysed the ability of each H1 histone variant to allow the H1-H1 interactions that are essential for the formation of the higher levels of chromatin structure, and we investigated the role played by the poly(ADP-ribosyl)ation process. Cross-linking analysis showed that H1e is the only somatic variant which, when bound to DNA, is able to produce H1-H1 polymers; the size of polymers was decreased when H1e was enriched in its poly(ADP-ribosyl)ated isoform. Measurement of the methyl-accepting ability in native nuclei compared with nuclei in which poly(ADP-ribosyl)ation was induced showed that the poly(ADP-ribosyl)ated H1 histone had not been removed from linker regions, in spite of its different interaction with DNA.

Specific inhibitory effect of H1e histone somatic variant on in vitro DNA-methylation process.

H1e and H1c histone variants were purified from mouse L929 fibroblasts using a reverse phase HPLC, and their effect on in vitro DNA methylation was investigated, together with their ability to bind unmethylated or methylated CpG-rich 44bp oligonucleotides. In a "physiological" range of H1:DNA ratios only H1e, at variance from H1c, was found to cause a marked inhibition of in vitro enzymic DNA methylation. It was also shown that both variants have a similar affinity in binding a methylated CpG-rich oligonucleotide, but that the binding to the same oligonucleotide in the unmethylated form occurs preferentially with H1e rather than with H1c. H1e is therefore likely to be directly involved in maintaining CpG-rich sequences in the unmethylated state.

Does hypomethylation of linker DNA play a role in chromatin condensation.

The inhibitory effect that H1 histone exerts on the in vitro DNA methylation process, catalysed by mammalian DNA methyltransferase, together with the relative hypomethylation of linker DNA in eukaryotic cells chromatin, suggest that this hypomethylated state of linker DNA can be of importance in allowing or regulating H1-dependent chromatin condensation. In native oligonucleosomes (olnu), i.e., in chromatin fragments consisting of 5-20 nucleosomes each, there was a correlation between the effects of H1 on the DNA ellipticity at 280 nm and the in vitro assayed methyl-accepting ability. The same was true in H1-depleted or in H1-reconstituted preparations. Artificial methylation caused olnu DNA to lose its ability to allow cooperative H1-H1 interactions under ionic strength conditions similar to those known to affect the transition of the 10-nm filament to the 30-nm chromatin fiber. These results suggest that hypomethylation of linker DNA plays a role in the H1-H1 interactions that are needed for solenoid condensation.

Specific variants of H1 histone regulate CpG methylation in eukaryotic DNA.

Upon HPLC fractionation of human placenta or calf thymus H1 histone preparations, only some fractions enriched in the H1e-c variants were able to exert a severe inhibition on in vitro enzymatic DNA methylation. These fractions, though similar to the other variants in interacting with genomic DNA, were also the only ones which could bind CpG-rich ds-oligodeoxyribonucleotides (oligos). Both the 6-CpG ds-oligo and the DNA purified from chromatin fractions enriched in 'CpG islands' were good competitors for the binding of H1e-c to the 6meCpG ds-oligo. This ability to bind any DNA sequence and to suppress the enzymatic methylation in any sequence containing CpG dinucleotides suggests, for these particular H1 variants, a possible role in maintaining CpG island DNA and linker DNA at low methylation levels.

Binding of histone H1e-c variants to CpG-rich DNA correlates with the inhibitory effect on enzymic DNA methylation.

Within the H1 histone family, only some fractions enriched in the H1e-c variants are effective in causing a marked inhibition, in vitro, of enzymic DNA methylation and, in gel retardation and Southwestern blot experiments, in binding double-stranded (ds) CpG-rich oligonucleotides. Both the 6-CpG ds-oligonucleotide and the DNA purified from chromatin fractions enriched in 'CpG islands' are good competitors for the binding of H1e-c to 6-meCpG ds-oligonucleotide. Because of their ability to bind any DNA sequence and to suppress the enzymic methylation in any sequence containing CpG dinucleotides, these particular H1 variants could play some role in maintaining linker DNA at low methylation levels and even in preserving the unmethylated state of the CpG-rich islands which characterize the promoter regions of housekeeping genes.