Shinichiro Chuma

5.9k total citations
54 papers, 4.7k citations indexed

About

Shinichiro Chuma is a scholar working on Molecular Biology, Genetics and Plant Science. According to data from OpenAlex, Shinichiro Chuma has authored 54 papers receiving a total of 4.7k indexed citations (citations by other indexed papers that have themselves been cited), including 46 papers in Molecular Biology, 21 papers in Genetics and 21 papers in Plant Science. Recurrent topics in Shinichiro Chuma's work include Chromosomal and Genetic Variations (21 papers), CRISPR and Genetic Engineering (18 papers) and Sperm and Testicular Function (15 papers). Shinichiro Chuma is often cited by papers focused on Chromosomal and Genetic Variations (21 papers), CRISPR and Genetic Engineering (18 papers) and Sperm and Testicular Function (15 papers). Shinichiro Chuma collaborates with scholars based in Japan, United States and France. Shinichiro Chuma's co-authors include Norio Nakatsuji, Mihoko Hosokawa, Ramesh S. Pillai, Takashi Tanaka, Toru Nakano, M. Reuter, Ravi Sachidanandam, Toshiaki Noce, Satomi Kuramochi‐Miyagawa and Takashi Shinohara and has published in prestigious journals such as Nature, Proceedings of the National Academy of Sciences and Nucleic Acids Research.

In The Last Decade

Shinichiro Chuma

53 papers receiving 4.6k citations

Peers

Shinichiro Chuma
Christa Heyting Netherlands
Toshiaki Noce Japan
Peter B. Møens Canada
P. Jeremy Wang United States
Willy M. Baarends Netherlands
Satomi Kuramochi‐Miyagawa Japan
Ricardo Benavente Germany
Angélique Girard United States
Frédéric Baudat France
Petr Svoboda Czechia
Christa Heyting Netherlands
Shinichiro Chuma
Citations per year, relative to Shinichiro Chuma Shinichiro Chuma (= 1×) peers Christa Heyting

Countries citing papers authored by Shinichiro Chuma

Since Specialization
Citations

This map shows the geographic impact of Shinichiro Chuma's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Shinichiro Chuma with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Shinichiro Chuma more than expected).

Fields of papers citing papers by Shinichiro Chuma

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Shinichiro Chuma. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Shinichiro Chuma. The network helps show where Shinichiro Chuma may publish in the future.

Co-authorship network of co-authors of Shinichiro Chuma

This figure shows the co-authorship network connecting the top 25 collaborators of Shinichiro Chuma. A scholar is included among the top collaborators of Shinichiro Chuma based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Shinichiro Chuma. Shinichiro Chuma is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
Tanaka, Yuki, Shin Kadota, Jian Zhao, et al.. (2023). Mature human induced pluripotent stem cell-derived cardiomyocytes promote angiogenesis through alpha-B crystallin. Stem Cell Research & Therapy. 14(1). 240–240. 5 indexed citations
2.
3.
Barnum, Carrie E., Catherine Y. Cheng, Deepti Anand, et al.. (2020). The Tudor-domain protein TDRD7, mutated in congenital cataract, controls the heat shock protein HSPB1 (HSP27) and lens fiber cell morphology. Human Molecular Genetics. 29(12). 2076–2097. 25 indexed citations
4.
Shiromoto, Yusuke, Satomi Kuramochi‐Miyagawa, Ippei Nagamori, et al.. (2019). GPAT2 is required for piRNA biogenesis, transposon silencing, and maintenance of spermatogonia in mice†. Biology of Reproduction. 101(1). 248–256. 15 indexed citations
5.
Yoshimura, Takuji, Toshiaki Watanabe, Satomi Kuramochi‐Miyagawa, et al.. (2018). Mouse GTSF 1 is an essential factor for secondary pi RNA biogenesis. EMBO Reports. 19(4). 46 indexed citations
6.
Kabayama, Yuka, Hidehiro Toh, Takayuki Sakurai, et al.. (2017). Roles of MIWI, MILI and PLD6 in small RNA regulation in mouse growing oocytes. Nucleic Acids Research. 45(9). gkx027–gkx027. 45 indexed citations
7.
Shiromoto, Yusuke, Satomi Kuramochi‐Miyagawa, Shinichiro Chuma, et al.. (2013). GPAT2, a mitochondrial outer membrane protein, in piRNA biogenesis in germline stem cells. RNA. 19(6). 803–810. 56 indexed citations
8.
Pillai, Ramesh S. & Shinichiro Chuma. (2012). piRNAs and their involvement in male germline development in mice. Development Growth & Differentiation. 54(1). 78–92. 112 indexed citations
9.
Wang, Jianquan, Jonathan P. Saxe, Takashi Tanaka, Shinichiro Chuma, & Haifan Lin. (2009). Mili Interacts with Tudor Domain-Containing Protein 1 in Regulating Spermatogenesis. Current Biology. 19(8). 640–644. 143 indexed citations
10.
Shoji, Masanobu, Takashi Tanaka, Mihoko Hosokawa, et al.. (2009). The TDRD9-MIWI2 Complex Is Essential for piRNA-Mediated Retrotransposon Silencing in the Mouse Male Germline. Developmental Cell. 17(6). 775–787. 273 indexed citations
11.
Vagin, Vasily V., James A. Wohlschlegel, Jun Qu, et al.. (2009). Proteomic analysis of murine Piwi proteins reveals a role for arginine methylation in specifying interaction with Tudor family members. Genes & Development. 23(15). 1749–1762. 259 indexed citations
12.
Reuter, M., Shinichiro Chuma, Takashi Tanaka, et al.. (2009). Loss of the Mili-interacting Tudor domain–containing protein-1 activates transposons and alters the Mili-associated small RNA profile. Nature Structural & Molecular Biology. 16(6). 639–646. 217 indexed citations
13.
Kanatsu‐Shinohara, Mito, Masanori Takehashi, Seiji Takashima, et al.. (2008). Homing of Mouse Spermatogonial Stem Cells to Germline Niche Depends on β1-Integrin. Cell stem cell. 3(5). 533–542. 147 indexed citations
14.
Hasegawa, Kouichi, Shinichiro Chuma, Takashi Tada, et al.. (2006). Testatin transgenic and knockout mice exhibit normal sex-differentiation. Biochemical and Biophysical Research Communications. 341(2). 369–375. 6 indexed citations
15.
Shoji, Masanobu, Shinichiro Chuma, Kayo Yoshida, Takashi Morita, & Norio Nakatsuji. (2005). RNA interference during spermatogenesis in mice. Developmental Biology. 282(2). 524–534. 43 indexed citations
16.
Chuma, Shinichiro, Mito Kanatsu-Shinohara, Kimiko Inoue, et al.. (2004). Spermatogenesis from epiblast and primordial germ cells following transplantation into postnatal mouse testis. Development. 132(1). 117–122. 104 indexed citations
17.
Chuma, Shinichiro, Masateru Hiyoshi, Akitsugu Yamamoto, et al.. (2003). Mouse Tudor Repeat-1 (MTR-1) is a novel component of chromatoid bodies/nuages in male germ cells and forms a complex with snRNPs. Mechanisms of Development. 120(9). 979–990. 102 indexed citations
18.
Tamura, Masaru, et al.. (2001). Pod-1/Capsulin shows a sex- and stage-dependent expression pattern in the mouse gonad development and represses expression of Ad4BP/SF-1. Mechanisms of Development. 102(1-2). 135–144. 51 indexed citations
19.
Chuma, Shinichiro & Norio Nakatsuji. (2001). Autonomous Transition into Meiosis of Mouse Fetal Germ Cells in Vitro and Its Inhibition by gp130-Mediated Signaling. Developmental Biology. 229(2). 468–479. 165 indexed citations
20.
Tamura, Masaru, et al.. (1999). A cystatin-related gene, testatin/cresp, shows male-specific expression in germ and somatic cells from the initial stage of murine gonadal sex-differentiation. The International Journal of Developmental Biology. 43(8). 777–784. 15 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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