Homologous recombinational repair ( HR ) is one of the major repair systems for DNA double‐strand breaks. RAD 51 is a key molecule in HR , and the RAD 51 concentration in the cell nucleus increases after DNA damage induction. However, the mechanism that regulates the intracellular distribution of RAD 51 is still unclear. Here, we show that hCAS / CSE 1L associates with RAD 51 in human cells. We found that hCAS / CSE 1L negatively regulates the nuclear protein level of RAD 51 under normal conditions. hCAS / CSE 1L is also required to repress the DNA damage‐induced focus formation of RAD 51. Moreover, we show that hCAS / CSE 1L plays roles in the regulation of the HR activity and in chromosome stability. These findings suggest that hCAS / CSE 1L is responsible for controlling the HR activity by directly interacting with RAD 51.
Abstract Master transcription factors regulate cell-type-specific gene expression to define cellular identities. One such gene, GATA3, is a key regulator of multiple cellular programs, including T lymphocyte development, mammary luminal epithelial cell differentiation and trophoblast development. Recently, comprehensive genomic analysis has identified GATA3 as one of the most frequently mutated genes in breast cancer. It is also known that GATA3 expression levels directly correlate with favorable prognosis. These findings strongly suggest that GATA3 plays a critical role in tumorigenesis. However, the molecular mechanism(s) underlying GATA3-mediated gene regulation in breast cancer cells is not clearly defined. GATA3 participates in a complicated regulatory network with FOXA1 and ER-alpha, governing the transcriptional program in luminal tumors. Biochemical analyses indicate that: (1) GATA3 binds to chromatin in an estrogen-independent manner, (2) GATA3 acts upstream of FOXA1. These studies suggest GATA3 may act as a pioneer factor, which is capable of independently associating with closed chromatin and modulating chromatin structure to establish an active enhancer. In order to investigate GATA3 function as a pioneer transcription factor, we chose the MDA-MB-231 breast cancer cell line, which is GATA3, FOXA1 and ER-alpha negative, and established stable cell lines expressing wild-type GATA3 or GFP as a control. Consistent with previous results, GATA3-expressing cells represented an epithelial phenotype at the cellular and molecular level. To determine whether GATA3 can direct reprogramming of chromatin conformation, we performed genome-wide analyses of the chromatin binding activity of GATA3 and its impact on histone modifications and chromatin structure. We will present recent results describing how GATA3 licenses enhancer function to direct the luminal transcriptional program. Citation Format: Motoki Takaku, Sara A. Grimm, Takashi Shimbo, Lalith Perera, Shinichi Machida, Hitoshi Kurumizaka, Paul A. Wade. GATA3 modulates chromatin structure to establish active enhancers in breast cancer cells. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 964. doi:10.1158/1538-7445.AM2015-964
Abstract Post-translational histone modifications are major regulators of gene expression. However, conventional immunoassays do not provide sufficient information regarding their spatial and temporal dynamic changes. Fluorescence/Förster resonance energy transfer (FRET)-based probes are capable of monitoring the dynamic changes associated with histone modifications in real-time by measuring the balance between histone-modifying enzyme activities. Recently, a genetically encoded histone-modification fluorescent probe using a single-chain variable region (scFv) fragment of a specific antibody was developed. The probe, modification-specific intracellular antibody, is capable of monitoring histone-acetylation levels in both cultured cells and living organisms based on the ratio of fluorescence intensities between the cell nucleus and cytoplasm. In this study, we constructed a FRET probe composed of yellow fluorescent protein attached at the N-terminus of an acetyl H3K9-specific scFv, tethered to a cyan fluorescent protein. When the FRET probe was expressed in human cells, both FRET efficiency and fluorescence intensity in the nucleus increased following histone-deacetylase inhibitor treatment. Using these two parameters, endogenous histone-acetylation levels were quantified over a high dynamic range. This probe provides a simple approach to quantify spatial and temporal dynamic changes in histone acetylation.
Histone H3.Y is a primate-specific, distant H3 variant. It is evolutionarily derived from H3.3, and may function in transcription regulation. However, the mechanism by which H3.Y regulates transcription has not been elucidated. In the present study, we determined the crystal structure of the H3.Y nucleosome, and found that many H3.Y-specific residues are located on the entry/exit sites of the nucleosome. Biochemical analyses revealed that the DNA ends of the H3.Y nucleosome were more flexible than those of the H3.3 nucleosome, although the H3.Y nucleosome was stable in vitro and in vivo. Interestingly, the linker histone H1, which compacts nucleosomal DNA, appears to bind to the H3.Y nucleosome less efficiently, as compared to the H3.3 nucleosome. These characteristics of the H3.Y nucleosome are also conserved in the H3.Y/H3.3 heterotypic nucleosome, which may be the predominant form in cells. In human cells, H3.Y preferentially accumulated around transcription start sites (TSSs). Taken together, H3.Y-containing nucleosomes around transcription start sites may form relaxed chromatin that allows transcription factor access, to regulate the transcription status of specific genes.
We discuss on the validity and approximation method of the adiabatic nuclear potentials, especially of the fourth order nuclear potential derived from pseudoscalar meson theory. In §2, it is shown that effects of time component of pseudovector coupling on the pseudoscalar meson potential are not large when distance between two nucleons is larger than about half of the force range. In §3, time variation of nucleon spin and τ-spin are evaluated for phenomenological and meson potentials, and critical radii for their applicability are derived. In §4, implications of the velocity-dependent forces in the interior region are discussed, and largeness of the purely quantum mechanical effects in the meson theory is pointed out. Hamiltonian for a two nucleon system in the intermediate coupling approximation is given. In §5, features of the meson-nucleon interaction are compared with that of the photon-electron interaction. It is pointed out that the transition matrix of the nucleon-nucleon collision is not analytic with respect to nucleon energy at the threshold for meson production. An ambiguity occurs when one intend to calculate the sixth order nuclear potential.
Linker histones bind to nucleosomes and compact polynucleosomes into a higher-order chromatin configuration. Somatic and germ cell-specific linker histone subtypes have been identified and may have distinct functions. In this study, we reconstituted polynucleosomes containing human histones H1.2 and H1T, as representative somatic and germ cell-specific linker histones, respectively, and found that H1T forms less compacted chromatin, as compared to H1.2. An in vitro homologous pairing assay revealed that H1T weakly inhibited RAD51/RAD54-mediated homologous pairing in chromatin, although the somatic H1 subtypes, H1.0, H1.1, H1.2, H1.3, H1.4, and H1.5, substantially suppressed it. An in vivo recombination assay revealed that H1T overproduction minimally affected the recombination frequency, but significant suppression was observed when H1.2 was overproduced in human cells. These results suggested that the testis-specific linker histone, H1T, possesses a specific function to produce the chromatin architecture required for proper chromosome regulation, such as homologous recombination.
Abstract Replication of genetic material involves the creation of characteristic termini. Determining these termini is important to refine our understanding of the mechanisms involved in maintaining the genomes of cellular organisms and viruses. Here we describe a computational approach combining direct and indirect readouts to detect termini from next-generation short-read sequencing. While a direct inference of termini can come from mapping the most prominent start positions of captured DNA fragments, this approach is insufficient in cases where the DNA termini are not captured, whether for biological or technical reasons. Thus, a complementary (indirect) approach to terminus detection can be applied, taking advantage of the imbalance in coverage between forward and reverse sequence reads near termini. A resulting metric (“strand bias”) can be used to detect termini even where termini are naturally blocked from capture or ends are not captured during library preparation (e.g., in tagmentation-based protocols). Applying this analysis to datasets where known DNA termini are present, such as from linear double-stranded viral genomes, yielded distinct strand bias signals corresponding to these termini. To evaluate the potential to analyze a more complex situation, we applied the analysis to examine DNA termini present early after HIV infection in a cell culture model. We observed both the known termini expected based on standard models of HIV reverse transcription (the U5-right-end and U3-left-end termini) as well as a signal corresponding to a previously described additional initiation site for plus-strand synthesis (cPPT [central polypurine tract]). Interestingly, we also detected putative terminus signals at additional sites. The strongest of these are a set that share several characteristics with the previously characterized plus-strand initiation sites (the cPPT and 3’ PPT [polypurine tract] sites): (i) an observed spike in directly captured cDNA ends, an indirect terminus signal evident in localized strand bias, (iii) a preference for location on the plus-strand, (iv) an upstream purine-rich motif, and (v) a decrease in terminus signal at late time points after infection. These characteristics are consistent in duplicate samples in two different genotypes (wild type and integrase-lacking HIV). The observation of distinct internal termini associated with multiple purine-rich regions raises a possibility that multiple internal initiations of plus-strand synthesis might contribute to HIV replication.
The original version of this Article contained an error in the spelling of the author Laurence Faivre, which was incorrectly given as Laurence Faive. This has now been corrected in both the PDF and HTML versions of the Article.
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