Rchr

J-GLOBAL ID：200901094952584750 Update date: Mar. 19, 2024

Shinohara Akira

シノハラアキラ | Shinohara Akira

Affiliation and department：
Job title： Professor
Homepage URL (1)： http://www.protein.osaka-u.ac.jp/genome/index.html

Research field (2)： Molecular biology , Genetics

Research keywords (1)：分子生物学

Research theme for competitive and other funds (34)：

2019 - 2022 Molecular mechanisms of control of recombination by dynamics of RAD51/DMC1-DNA complexes
2015 - 2020 Chromosome OS
2015 - 2020 Control of chromosome functions by axis-loop structure (chromosome 3D) during meiosis
2016 - 2019 Molecular mechanism of partner choice for recombination by two RecA homologs
2014 - 2016 Functions of nuclear actin filament and its mechanism of the formation

2010 - 2016 Systematic understanding of genome adaptation

2010 - 2015 Systematic study of chromosome adaptation

2010 - 2015 Chromosome dynamics and genome adaptation during meiosis

2011 - 2014 Understanding of molecular mechanism of the assembly of two RecA homologs, Rad51 and Dmc1

2009 - 2010 パキテンチェックポイントにおけるヒストン修飾の機能

2009 - 2010 SCF(cdc4)ユビキチンリガーゼによる染色体形成制御

2008 - 2010 Regulatory mechanisms of meiotic recombination through movements and morphogenesis of chromosomes

2005 - 2009 The network regulating the chromosome cycle

2005 - 2009 Molecular mechanism of the connection between chromosome networks and recombination

2005 - 2005 酵母並びにヒト細胞における相同組換えの分子メカニズムとゲノム安定化

2004 - 2005 Analysis of molecular mechanism of homologous recombination in eukaryotes

2001 - 2005 Homologous recombination and gene amplification induced by DNA replication fork inhibition

2004 - 2004 相同組換えによるゲノム安定化を介した発がんの防御

2003 - 2003 染色体上で減数分裂期交叉型組換えの"数"を数える仕組み

1999 - 2003 Molecular mechanisms of generation of pleiotropic effects of recombination genes

1996 - 1999 DNA組換えと組換え修復の普遍的機構

1997 - 1998 組換え遺伝子RAD51とDNAトランスアクションの遺伝的解析

1994 - 1998 Study on Genetic Recombination Systems in Eukaryotes

1997 - 1997 減数分裂期組換えにおける2つのRecA様蛋白質の機能分化の解析

1996 - 1996 真核生物の遺伝的組換えの試験管内反応系の確立

1996 - 1996 真核生物の遺伝的組換えの分子機構の解析

1996 - 1996 減数分裂期組換えにおける2つのRecA様蛋白質の機能分化の解析

1994 - 1995 Functional Analysis of Recombination Proteins in Eukaryotes

減数分裂期組換えの分子生物学的解析

酵母Rad51、Rad52蛋白質の生化学的解析

ヒト、マウスの組換え遺伝子RAD51の機能解析

Molecular analysis of meiotic recombination

Biochemical characterization of yeast Rad51、Rad52 proteins

Studies on function of recombination gene, RAD51, in human and mouse

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Papers (94)：

Jeong H Joo, Soogil Hong, Mika T Higashide, Eui-Hwan Choi, Seobin Yoon, Min-Su Lee, Hyun Ah Kang, Akira Shinohara, Nancy Kleckner, Keun P Kim. RPA interacts with Rad52 to promote meiotic crossover and noncrossover recombination. Nucleic Acids Research. 2024
Suman Dash, Sameer Joshi, Ajith V Pankajam, Akira Shinohara, Koodali T Nishan. Heterozygosity alters Msh5 binding to meiotic chromosomes in the baker’s yeast. Genetics. 2023
Masaru Ito, Yurika Fujita, Akira Shinohara. Positive and negative regulators of RAD51/DMC1 in homologous recombination and DNA replication. DNA Repair. 2023. 103613-103613
Ghanim Fajish V, Kiran Challa, Sagar Salim, Ajith VP, Stephen Mwaniki, Ruihao Zhang, Yurika Fujita, Masaru Ito, Nishant K.T, Akira Shinohara. DNA double-strand breaks regulate the cleavage-independent release of Rec8-cohesin during yeast meiosis. Genes-to-Cells. 2023. in press
Sijia Liu, Akira Shinohara, Asako Furukohri. Fanconi anemia-associated mutation in RAD51 compromises the coordinated action of DNA binding and ATPase activities. Journal of Biological Chemistry. 2023. 105424-105424

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MISC (52)：

Li W, Zhang L, Shinohara A, Keeney S. Editorial: Meiosis: From Molecular Basis to Medicine. Frontier in Cellularl and Developmental Biology. 2021. 9. 812292
G.N. Krishnaprasada, V.P. Ajith, Shinohara, M, Chakraborty, P, Lin, G. Steinmetz, L.M, Shinohara, A, Nishant K.T. The baker’s yeast Msh4-Msh5 binds to double-strand break hotspots distant to chromosome axis to promote crossovers. BioRxiv. 2020
Tomoko Takagi, Masako Osumi, Akira Shinohara. Nuclear actin cable with multiple branches during yeast meiosis. BioRxiv. 2019
Challa Kiran, Miki Shinohara, Akira Shinohara. Prophase pathway of arm-cohesin removal in budding yeast meiosis. GENES & GENETIC SYSTEMS. 2014. 89. 6. 278-278
Terasawa, Masahiro, Shinohara, Akira, Shinohara, Miki. Double-strand break repair-adox: Restoration of suppressed double-strand break repair during mitosis induces genomic instability. CANCER SCIENCE. 2014. 105. 12. 1519-1525

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Lectures and oral presentations (20)：

Fignl1 AAA+ ATPase modulates the dynamics of Rad51 and Dmc1 ensembles
(Chromosome stability 2022 2022)
減数分裂期のDNA交換と染色体構造形成の制御のメカニズム
(神戸大学理学部生物科学科セミナー 2022)
Fignl1 AAA+ ATPase modulates the dynamics of Rad51 and Dmc1 ensembles
(FASEB meeting on recombination and genome rearrangement 2022)
Control of homologous recombination during meiosis and mitosis
(ANSC Reproductive Physiology, University of Illinois at Urbana-Champaign Urbana, USA 2022)
Human RAD51 paralog, SWSAP1, promotes RAD51 assembly by regulating the anti-recombinase, FIGNL1 AAA+ ATPase
(Seminar at IISER Thiruvananthapuram 2019)

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Works (12)：

減数分裂期染色体機能部位におけるプロテインプロファイリング
2004 -
減数分裂期組換えと生殖細胞形成
2004 -
相同組換えによるゲノム安定化を介した発ガンの防御
2004 -
真核生物の相同組換えの分子メカニズムの解明
2004 -
酵母Rad52蛋白質の生化学的解析
1990 - 1993

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Education (5)：

1988 - 1991 Osaka Univ. Graduate School of Science
- 1991 Osaka University Graduate School, Division of Natural Science
1986 - 1988 Osaka University Graduate School of Science
1982 - 1986 Osaka Univ. School of Science Department of Biology
- 1986 Osaka University Faculty of Science

Professional career (2)：

Ph.D. (Osaka University)
(BLANK)

Work history (9)：

2001 - 2003 大阪大学院理学研究科助教授
2003 - - 大阪大学たんぱく質研究所教授
2001 - - Osaka Univ. Graduate School of Science, Assistant Prof.
1999 - 2000 シカゴ大学準教授
1999 - 2000 University of Chicago, Assistant Professor

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Awards (3)：

2021/04 - Awards for Science and Technology Study on molecular mechanism of homologous recombination
2009 - 大阪市大阪府大阪科学技術センター大阪科学賞
1992 - 日本分子生物学会東燃研究奨励賞

Association Membership(s) (1)：

日本分子生物学会

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