Single-Molecule Approaches Reveal the Idiosyncrasies of RNA Polymerases

Recently developed single-molecule techniques have provided new insights into the function of one of the most complex and highly regulated processes in the cell—the transcription of the DNA template into RNA. This review discusses methods and results from this emerging field, and it puts them in perspective of existing biochemical and structural data

The middle region of an HP1-binding protein, HP1-BP74, associates with linker DNA at the entry/exit site of nucleosomal DNA

Kayoko Hayashihara, Susumu Uchiyama, Shigeru Shimamoto, Shouhei Kobayashi, Miroslav Tomschik, Hidekazu Wakamatsu, Daisuke No, Hiroki Sugahara, Naoto Hori, Masanori Noda, Tadayasu Ohkubo, Jordanka Zlatanova, Sachihiro Matsunaga, Kiichi Fukui. The Middle Region of an HP1-binding Protein, HP1-BP74, Associates with Linker DNA at the Entry/Exit Site of Nucleosomal DNA. Journal of Biological Chemistry, Volume 285, Issue 9, 2010, Pages 6498-6507. https://doi.org/10.1074/jbc.M109.092833

Chromatin Fiber Dynamics under Tension and Torsion

Genetic and epigenetic information in eukaryotic cells is carried on chromosomes, basically consisting of large compact supercoiled chromatin fibers. Micromanipulations have recently led to great advances in the knowledge of the complex mechanisms underlying the regulation of DNA transaction events by nucleosome and chromatin structural changes. Indeed, magnetic and optical tweezers have allowed opportunities to handle single nucleosomal particles or nucleosomal arrays and measure their response to forces and torques, mimicking the molecular constraints imposed in vivo by various molecular motors acting on the DNA. These challenging technical approaches provide us with deeper understanding of the way chromatin dynamically packages our genome and participates in the regulation of cellular metabolism

Parp1 Localizes within the Dnmt1 Promoter and Protects Its Unmethylated State by Its Enzymatic Activity

Aberrant hypermethylation of CpG islands in housekeeping gene promoters and widespread genome hypomethylation are typical events occurring in cancer cells. The molecular mechanisms behind these cancer-related changes in DNA methylation patterns are not well understood. Two questions are particularly important: (i) how are CpG islands protected from methylation in normal cells, and how is this protection compromised in cancer cells, and (ii) how does the genome-wide demethylation in cancer cells occur. The latter question is especially intriguing since so far no DNA demethylase enzyme has been found.Our data show that the absence of ADP-ribose polymers (PARs), caused by ectopic over-expression of poly(ADP-ribose) glycohydrolase (PARG) in L929 mouse fibroblast cells leads to aberrant methylation of the CpG island in the promoter of the Dnmt1 gene, which in turn shuts down its transcription. The transcriptional silencing of Dnmt1 may be responsible for the widespread passive hypomethylation of genomic DNA which we detect on the example of pericentromeric repeat sequences. Chromatin immunoprecipitation results show that in normal cells the Dnmt1 promoter is occupied by poly(ADP-ribosyl)ated Parp1, suggesting that PARylated Parp1 plays a role in protecting the promoter from methylation.In conclusion, the genome methylation pattern following PARG over-expression mirrors the pattern characteristic of cancer cells, supporting our idea that the right balance between Parp/Parg activities maintains the DNA methylation patterns in normal cells. The finding that in normal cells Parp1 and ADP-ribose polymers localize on the Dnmt1 promoter raises the possibility that PARylated Parp1 marks those sequences in the genome that must remain unmethylated and protects them from methylation, thus playing a role in the epigenetic regulation of gene expression

CCCTC-Binding Factor Meets Poly(ADP-Ribose) Polymerase-1

CCCTC-binding factor (CTCF) is a ubiquitous Zn-finger-containing protein with numerous recognized functions, including, but not limited to, gene activation and repression, enhancer-blocking, X-chromosome inactivation, and gene imprinting. It is believed that the protein performs such a variety of functions by interacting with an array of very diverse proteins. In addition, CTCF undergoes several post-translational modifications, including poly(ADP-ribosyl)ation. The PARylated form of CTCF has recently been implicated in two important functions: gene imprinting and control of ribosomal gene transcription. Here, we summarize and critically discuss the available data on the interplay between CTCF and poly(ADP-ribosyl)ation in these two processes. We consider the newly described phenomena in the broader context of PARP's activities, including the crucial role of protein PARylation in the regulation of the genome methylation pattern

DNA methylation and chromatin structure

[No abstract available