Your search keyword '"Asuka Kamio"' showing total 4 results

1. Comprehensive epigenome characterization reveals diverse transcriptional regulation across human vascular endothelial cells

Author

Ryuichiro Nakato, Youichiro Wada, Ryo Nakaki, Genta Nagae, Yuki Katou, Shuichi Tsutsumi, Natsu Nakajima, Hiroshi Fukuhara, Atsushi Iguchi, Takahide Kohro, Yasuharu Kanki, Yutaka Saito, Mika Kobayashi, Akashi Izumi-Taguchi, Naoki Osato, Kenji Tatsuno, Asuka Kamio, Yoko Hayashi-Takanaka, Hiromi Wada, Shinzo Ohta, Masanori Aikawa, Hiroyuki Nakajima, Masaki Nakamura, Rebecca C. McGee, Kyle W. Heppner, Tatsuo Kawakatsu, Michiru Genno, Hiroshi Yanase, Haruki Kume, Takaaki Senbonmatsu, Yukio Homma, Shigeyuki Nishimura, Toutai Mitsuyama, Hiroyuki Aburatani, Hiroshi Kimura, and Katsuhiko Shirahige

Subjects

Endothelial cells, Histone modifications, Epigenome database, ChIP-seq, Large-scale analysis, Genetics, QH426-470

Abstract

Abstract Background Endothelial cells (ECs) make up the innermost layer throughout the entire vasculature. Their phenotypes and physiological functions are initially regulated by developmental signals and extracellular stimuli. The underlying molecular mechanisms responsible for the diverse phenotypes of ECs from different organs are not well understood. Results To characterize the transcriptomic and epigenomic landscape in the vascular system, we cataloged gene expression and active histone marks in nine types of human ECs (generating 148 genome-wide datasets) and carried out a comprehensive analysis with chromatin interaction data. We developed a robust procedure for comparative epigenome analysis that circumvents variations at the level of the individual and technical noise derived from sample preparation under various conditions. Through this approach, we identified 3765 EC-specific enhancers, some of which were associated with disease-associated genetic variations. We also identified various candidate marker genes for each EC type. We found that the nine EC types can be divided into two subgroups, corresponding to those with upper-body origins and lower-body origins, based on their epigenomic landscape. Epigenomic variations were highly correlated with gene expression patterns, but also provided unique information. Most of the deferentially expressed genes and enhancers were cooperatively enriched in more than one EC type, suggesting that the distinct combinations of multiple genes play key roles in the diverse phenotypes across EC types. Notably, many homeobox genes were differentially expressed across EC types, and their expression was correlated with the relative position of each organ in the body. This reflects the developmental origins of ECs and their roles in angiogenesis, vasculogenesis and wound healing. Conclusions This comprehensive analysis of epigenome characterization of EC types reveals diverse transcriptional regulation across human vascular systems. These datasets provide a valuable resource for understanding the vascular system and associated diseases.

Published

2019

2. Sex-specific histone modifications in mouse fetal and neonatal germ cells

Author

Akihiko Sakashita, Hisato Kobayashi, Yuko Jincho, Yukiko Kawabata, Yasuhisa Matsui, Tomoya Takashima, Tomohiro Kono, and Asuka Kamio

Subjects

Epigenomics, Male, 0301 basic medicine, Cancer Research, Methylation, Germline, Histones, Transcriptome, Mice, 03 medical and health sciences, Fetus, 0302 clinical medicine, Genetics, Animals, Epigenetics, biology, Chromatin, Cell biology, Mice, Inbred C57BL, Germ Cells, 030104 developmental biology, Histone, Animals, Newborn, 030220 oncology & carcinogenesis, DNA methylation, biology.protein, H3K4me3, Female, Chromatin immunoprecipitation

Abstract

Aims: Epigenetic signatures of germline cells are dynamically reprogrammed to induce appropriate differentiation, development and sex specification. We investigated sex-specific epigenetic changes in mouse fetal germ cells (FGCs) and neonatal germ cells. Materials & methods: Six histone marks in mouse E13.5 FGCs and P1 neonatal germ cells were analyzed by chromatin immunoprecipitation and sequencing. These datasets were compared with transposase-accessible chromatin sites, DNA methylation and transcriptome. Results: Different patterns of each histone mark were detected in female and male FGCs, and H3K4me3/H3K27me3 bivalent marks were enriched in different chromosomal regions of female and male FGCs. Conclusion: Our results suggest that histone modifications may affect FGC gene expression following DNA methylation erasure, contributing to the differentiation into female and male germ cells.

Published

2019

3. LTR retrotransposons transcribed in oocytes drive species-specific and heritable changes in DNA methylation

Author

Asuka Kamio, Mohammad M. Karimi, Julien Richard Albert, Kenjiro Shirane, Matthew C. Lorincz, Louis Lefebvre, Tomohiro Kono, Akihiko Sakashita, Hisato Kobayashi, Tasuku Koike, Aaron B. Bogutz, and Julie Brind’Amour

Subjects

0301 basic medicine, Retroelements, Transcription, Genetic, Science, Inheritance Patterns, General Physics and Astronomy, Retrotransposon, Biology, Synteny, Genome, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Species Specificity, Animals, Humans, RNA, Messenger, Epigenetics, lcsh:Science, Mammals, Regulation of gene expression, Genetics, Polymorphism, Genetic, Multidisciplinary, Terminal Repeat Sequences, Promoter, General Chemistry, DNA Methylation, Long terminal repeat, Rats, Mice, Inbred C57BL, 030104 developmental biology, Gene Expression Regulation, CpG site, Fertilization, DNA methylation, Oocytes, CpG Islands, DNA, Intergenic, lcsh:Q

Abstract

De novo DNA methylation (DNAme) during mouse oogenesis occurs within transcribed regions enriched for H3K36me3. As many oocyte transcripts originate in long terminal repeats (LTRs), which are heterogeneous even between closely related mammals, we examined whether species-specific LTR-initiated transcription units (LITs) shape the oocyte methylome. Here we identify thousands of syntenic regions in mouse, rat, and human that show divergent DNAme associated with private LITs, many of which initiate in lineage-specific LTR retrotransposons. Furthermore, CpG island (CGI) promoters methylated in mouse and/or rat, but not human oocytes, are embedded within rodent-specific LITs and vice versa. Notably, at a subset of such CGI promoters, DNAme persists on the maternal genome in fertilized and parthenogenetic mouse blastocysts or in human placenta, indicative of species-specific epigenetic inheritance. Polymorphic LITs are also responsible for disparate DNAme at promoter CGIs in distantly related mouse strains, revealing that LITs also promote intra-species divergence in CGI DNAme., De novo DNA methylation during mouse oogenesis occurs within transcribed regions. Here the authors investigate the role of species-specific long terminal repeats (LTRs)-initiated transcription units in regulating the oocyte methylome, identifying syntenic regions in mouse, rat and human with divergent DNA methylation associated with private LITs.

Published

2018

4. Essential roles of the histone methyltransferase ESET in the epigenetic control of neural progenitor cells during development

Author

Ryoichiro Kageyama, Keiko Takemoto, Yoichi Shinkai, Asuka Kamio-Miura, Miyuki Nishi, Matsui Toshiyuki, Siok-Lay Tan, Hiroyuki Aburatani, and Toshiyuki Ohtsuka

Subjects

Methyltransferase, Retroelements, Cellular differentiation, Neurogenesis, Down-Regulation, Mice, Transgenic, Epigenesis, Genetic, Mice, Neural Stem Cells, Gene expression, Animals, Epigenetics, Protein Methyltransferases, GABAergic Neurons, Molecular Biology, Cell Proliferation, Regulation of gene expression, Genetics, biology, Base Sequence, Sequence Analysis, RNA, Brain, Gene Expression Regulation, Developmental, Cell Differentiation, Histone-Lysine N-Methyltransferase, Cell biology, Histone, Histone methyltransferase, Astrocytes, biology.protein, Developmental Biology

Abstract

In the developing brain, neural progenitor cells switch differentiation competency by changing gene expression profiles that are governed partly by epigenetic control, such as histone modification, although the precise mechanism is unknown. Here we found that ESET (Setdb1), a histone H3 Lys9 (H3K9) methyltransferase, is highly expressed at early stages of mouse brain development but downregulated over time, and that ablation of ESET leads to decreased H3K9 trimethylation and the misregulation of genes, resulting in severe brain defects and early lethality. In the mutant brain, endogenous retrotransposons were derepressed and non-neural gene expression was activated. Furthermore, early neurogenesis was severely impaired, whereas astrocyte formation was enhanced. We conclude that there is an epigenetic role of ESET in the temporal and tissue-specific gene expression that results in proper control of brain development.

Published

2012