{"id":302,"date":"2021-10-30T05:40:33","date_gmt":"2021-10-30T05:40:33","guid":{"rendered":"https:\/\/smg.hiroshima-u.ac.jp\/?page_id=302"},"modified":"2021-10-30T06:12:18","modified_gmt":"2021-10-30T06:12:18","slug":"work","status":"publish","type":"page","link":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/work\/","title":{"rendered":"\u7814\u7a76\u5b9f\u7e3e"},"content":{"rendered":"<div id=\"main\">\n<p align=\"center\"><a href=\"#2021\">2021<\/a> |<a href=\"#2020\">2020<\/a> |<a href=\"#2019\">2019<\/a> |<a href=\"#2018\">2018<\/a> |<a href=\"#2017\">2017<\/a> |<a href=\"#2016\">2016<\/a> |<a href=\"#2015\">2015<\/a> |<a href=\"#2014\">2014<\/a> |<a href=\"#2013\">2013<\/a> | |<a href=\"#2012\">2012<\/a> | <a href=\"#2011\">2011<\/a> | <a href=\"#2010\">2010<\/a> | <a href=\"#2009\">2009<\/a> | <a href=\"#2008\">2008<\/a> | <a href=\"#2007\">2007<\/a><br \/>\n<a href=\"#2006\">2006<\/a> | <a href=\"#2005\">2005<\/a> | <a href=\"#2004\">2004<\/a> | <a href=\"#2003\">2003<\/a> | <a href=\"#2002\">2002<\/a> | <a href=\"#2000\">2000<\/a> | <a href=\"#1999\">1999<\/a> | <a href=\"#1998\">1998<\/a> | <a href=\"#1997\">1997<\/a> | <a href=\"#1996\">1996<\/a> | <a href=\"#1994\">1994<\/a><\/p>\n<p><a name=\"2021\"><\/a><\/p>\n<h3>2021\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work\">\n<dt>Nishinaka-Arai Y, Niwa A, Matsuo S, Kazuki Y, Yakura Y, Hiroma T, Toki T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Ito E, Oshimura M, Nakahata T and Saito MK<\/dt>\n<dd>Down syndrome-related transient abnormal myelopoiesis is attributed to a specific erythro-megakaryocytic subpopulation with GATA1 mutation<\/dd>\n<dd><em><strong>Haematologica<\/strong><\/em>, 106(2):635-640, 2021<\/dd>\n<dt>Pieplow A, Dastaw M, Sakuma T, Sakamoto N, Yamamoto T, Yajima M, Oulhen N, Wessel GM<\/dt>\n<dd>CRISPR-Cas9 editing of non-coding genomic loci as a means of controlling gene expression in the sea urchin<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>, 472:85-97, 2021<\/dd>\n<dt>Arima Y, Nakagawa Y, Takeo T, Ishida T, Yamada T, Hino S, Nakao M, Hanada S, Umemoto T, Suda T, Sakuma T, Yamamoto T, Watanabe T, Nagaoka K, Tanaka Y, Kawamura YK, Tonami K, Kurihara H, Sato Y, Yamagata K, Nakamura T, Araki S, Yamamoto E, Izumiya Y, Sakamoto K, Kaikita K, Matsushita K, Nishiyama K, Nakagata N, Tsujita K<\/dt>\n<dd>Murine neonatal ketogenesis preserves mitochondrial energetics by preventing protein hyperacetylation<\/dd>\n<dd><em><strong>Nature Metabolism<\/strong><\/em>, 3(2):196-210, 2021<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2\u3001\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>CRISPR\u6700\u65b0\u30c4\u30fc\u30eb\u30dc\u30c3\u30af\u30b9<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66\u3001\u7f8a\u571f\u793e<\/strong><\/em>, 2021<\/dd>\n<\/dl>\n<p><a name=\"2020\"><\/a><\/p>\n<h3>2020\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Li J, Hsu A, Hua Y, Wang G, Cheng L, <u>Ochiai H<\/u>, <u>Yamamoto T<\/u>, Pertsinidis A<\/dt>\n<dd>Single-gene imaging links genome topology, promoter\u2013enhancer communication and transcription control<\/dd>\n<dd><em><strong>Nature Structural &amp; Molecular Biology<\/strong><\/em>, 7(11):1032-1040, 2020<\/dd>\n<dt>Sanoh S, Hanada H, Kashiwagi K, Mori T, Goto-Inoue N, <u>Suzuki KT<\/u>, Mori J, Nakamura N, <u>Yamamoto T<\/u>, kiKitamura S, Kotake Y, Sugihara K, Ohta S, Kashiwagi A<\/dt>\n<dd>Amiodarone bioconcentration and suppression of metamorphosis in Xenopus<\/dd>\n<dd><em><strong>Aquatic Toxicology<\/strong><\/em>, 228:105623, 2020<\/dd>\n<dt><u>Kurita T<\/u>, Moroi K, Iwai M, Okazaki K, Shimizu S, Nomura S, Saito F, Maeda S, Takami A, Sakamoto A, Ohta H, <u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Efficient and multiplexable genome editing using Platinum TALENs in oleaginous microalga, Nannochloropsis oceanica NIES-2145<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>, 25(10):695-702, 2020<\/dd>\n<dt>Sekiguchi M, Sobue A, Kushima I, Wang C, Arioka Y, Kato H, Kodama A, Kubo H, Ito N, Sawahata M, Hada K, Ikeda R, Shinno M, Mizukoshi C, Tsujimura K, Yoshimi A, Ishizuka K, Takasaki Y, Kimura H, Xing J, Yu Y, Yamamoto M, Okada T, Shishido E, Inada T, Nakatochi M, Takano T, Kuroda K, Amano M, Aleksic B, <u>Yamamoto T<\/u>, <u>Sakuma T<\/u>, Aida T, Tanaka K, Hashimoto R, Arai M, Ikeda M, Iwata N, Shimamura T, Nagai T, Nabeshima T, Kaibuchi K, Yamada K, Mori D, Ozaki N.<\/dt>\n<dd>ARHGAP10, which encodes Rho GTPase-activating protein 10, is a novel gene for schizophrenia risk<\/dd>\n<dd><em><strong>Transl Psychiatry<\/strong><\/em>, 10(1):247, 2020<\/dd>\n<dt><u>Ochiai H<\/u>, Hayashi T, Umeda M, Yoshimura M, Harada A, Shimizu Y, Nakano K, Saitoh N, Liu Z, <u>Yamamoto T<\/u>, Okamura T, Ohkawa Y, Kimura H and Nikaido I<\/dt>\n<dd>Genome-wide kinetic properties of transcriptional bursting in mouse embryonic stem cells<\/dd>\n<dd><em><strong>Science Advances<\/strong><\/em>, in press, 2020<\/dd>\n<dt>Yaguchi S, Yaguchi J, Suzuki H, Kinjo S, Kiyomoto M, Ikeo K and <u>Yamamoto T<\/u><\/dt>\n<dd>Establishment of homozygous knock-out sea urchins<\/dd>\n<dd><em><strong>Current Biology<\/strong><\/em>, i30(10):R427-R429, 2020<\/dd>\n<dt>Miyamoto T, <u>Hosoba K<\/u>, Itabashi T, Iwane AH, Akutsu SN, <u>Ochiai H<\/u>, Saito Y, <u>Yamamoto T<\/u> and Matsuura S<\/dt>\n<dd>Insufficiency of ciliary cholesterol in hereditary Zellweger syndrome<\/dd>\n<dd><em><strong>The EMBO Journal<\/strong><\/em>, 39(12):e103499, 2020<\/dd>\n<dt>Fujii S, Tago T, <u>Sakamoto N<\/u>, <u>Yamamoto T<\/u>, Satoh T and Satoh A<\/dt>\n<dd>Recycling endosomes associate with Golgi stacks in sea urchin embryos<\/dd>\n<dd><em><strong>Communicative and Integrative Biology <\/strong><\/em>, 3(1):59-62, 2020<\/dd>\n<dt>Iida M, Suzuki M, Sakane Y, Nishide H, Uchiyama I, <u>Yamamoto T<\/u>, <u>Suzuki KI<\/u> and Fujii S<\/dt>\n<dd>A simple and practical workflow for genotyping of CRISPR\u2013Cas9\u2010based knockout phenotypes using multiplexed amplicon sequencing<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>, in press, 2020<\/dd>\n<dt>Takahashi M, Ikeda K, Ohmuraya M, Nakagawa Y, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Kawakami K<\/dt>\n<dd>Six1 is required for signaling center formation and labial-lingual asymmetry in developing lower incisors<\/dd>\n<dd><em><strong>Developmental Dynamics<\/strong><\/em>, 249(9):1098-1116, 2020<\/dd>\n<dt>Hozumi A, Matsunobu S, Mita K, Treen N, Sugihara T, Horie T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Shiraishi A, Hamada M, Satoh N, Sakurai K, Satake H and Sasakura Y<\/dt>\n<dd>GABA-Induced GnRH Release Triggers Chordate Metamorphosis<\/dd>\n<dd><em><strong>Current Biology<\/strong><\/em>, 30(8), 1555-1561.e4, 2020<\/dd>\n<dt>Ozawa K, Tsumoto H, Miura Y, Yamaguchi J, Iguchi-Ariga SMM, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Uchiyama Y<\/dt>\n<dd>DJ-1 is indispensable for the S-nitrosylation of Parkin, which maintains function of mitochondria<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 10, 4377, 2020<\/dd>\n<dt>George G, Ninagawa S, Yagi H, Saito T, Ishikawa T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Imami K, Ishihama Y, Kato K, Okada T and Mori K<\/dt>\n<dd>EDEM2 stably disulfide-bonded to TXNDC11 catalyzes the first mannose trimming step in mammalian glycoprotein ERAD<\/dd>\n<dd><em><strong>Elife<\/strong><\/em>, 9, pii: e53455, 2020<\/dd>\n<dt>Sawada H, Yamamoto K, Yamaguchi A, Yamada L, Higuchi A, Nukaya H, Fukuoka M, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Sasakura Y and Shirae-Kurabayashi M<\/dt>\n<dd>Three multi-allelic gene pairs are responsible for self-sterility in the ascidian Ciona intestinalis<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 10, 2514, 2020<\/dd>\n<dt>Shindo R, Katagiri T, Komazawa-Sakon S, Ohmuraya M, Takeda W, Nakagawa Y, Nakagata N, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Nishiyama C, Nishina T, Yamazaki S, Kameda H, Nakano H<\/dt>\n<dd>Regenerating islet-derived protein (Reg)3b plays a crucial role in attenuation of ileitis and colitis in mice<\/dd>\n<dd><em><strong>Biochem Biophys Rep<\/strong><\/em>, 21, 100738, 2020<\/dd>\n<dt>Teratake Y, Takashina T, Iijima K, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Ishizaka Y<\/dt>\n<dd>Development of a protein-based system for transient epigenetic repression of immune checkpoint molecule and enhancement of antitumour activity of natural killer cells<\/dd>\n<dd><em><strong>British Journal of Cancer<\/strong><\/em>, 122(6), 823-834, 2020<\/dd>\n<dt>Tajima Y, Hozumi A, Yoshida K, Treen N, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Sasakura Y<\/dt>\n<dd>Hox13 is essential for formation of a sensory organ at the terminal end of the sperm duct in Ciona<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>, 458(1), 120-131, 2020<\/dd>\n<dt>Koba H, Jin S, Imada N, Ishikawa T, Ninagawa S, Okada T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Mori K<\/dt>\n<dd>Reinvestigation of disulfide-bonded oligomeric forms of the unfolded protein response transducer ATF6<\/dd>\n<dd><em><strong>Cell Struct Funct.<\/strong><\/em>, 45(1), 9-21, 2020<\/dd>\n<dt>Konishi S, Tanaka N, Mashimo T, <u>Yamamoto T<\/u>, <u>Sakuma T<\/u>, Kaneko T, Tanaka M, Izawa T, Yamate J and Kuwamura M<\/dt>\n<dd>Pathological characteristics of Ccdc85c knockout rats: a rat model of genetic hydrocephalus<\/dd>\n<dd><em><strong>Experimental Animals<\/strong><\/em>, 69(1), 26-33, 2020<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Kunii A, <u>Yamamoto T<\/u> and <u>Sakuma T<\/u><\/dt>\n<dd>Various strategies of effector accumulation to improve the efficiency of genome editing and derivative methodologies<\/dd>\n<dd><em><strong>In Vitro Cellular &amp; Developmental Biology &#8211; Animal<\/strong><\/em>,\u00a0in press, 2020<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u3068\u306f\u306a\u306b\u304b<\/dd>\n<dd><em><strong>\u8b1b\u8ac7\u793e\u30d6\u30eb\u30fc\u30d0\u30c3\u30af\u30b9<\/strong><\/em>, 2020<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u672a\u6765<\/dd>\n<dd><em><strong>\u533b\u5b66\u306e\u3042\u3086\u307f<\/strong><\/em>,\u00a0\u4f01\u753b\uff082020\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\uff0c\u4e2d\u6751\u5fd7\u7a42, <u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u591a\u69d8\u5316\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u533b\u5b66\u306e\u3042\u3086\u307f\u5225\u518a\u300c\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u672a\u6765\u300d<\/strong><\/em>,\u00a0273:9, 700-707\uff082020\uff09<\/dd>\n<dt><u>\u843d\u5408\u3000\u535a<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u30c4\u30fc\u30eb<\/dd>\n<dd><em><strong>\u533b\u5b66\u306e\u3042\u3086\u307f\u5225\u518a\u300c\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u672a\u6765\u300d<\/strong><\/em>,\u00a0273:9, 709-715\uff082020\uff09<\/dd>\n<\/dl>\n<p><a name=\"2019\"><\/a><\/p>\n<h3>2019\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Morisaka H, Yoshimi K, Okuzaki Y, Gee P, Kunihiro Y, Sonpho E, Xu H, Sasakawa N, Naito Y, Nakada S, <u>Yamamoto T<\/u>, Sano S, Hotta A, Takeda J, Mashimo T<\/dt>\n<dd>CRISPR-Cas3 induces broad and unidirectional genome editing in human cells<\/dd>\n<dd><em><strong>Nat Commun.<\/strong><\/em>, 10(1): 5302, 2019<\/dd>\n<dt>Yasumoto S, Umemotoz, N, Lee HJ, Nakayasu M, Sawai S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Mizutani M, Saito K, Muranaka T<\/dt>\n<dd>Efficient genome engineering using Platinum TALEN in potato<\/dd>\n<dd><em><strong>Plant Biotechnology<\/strong><\/em>, 36: 167-173, 2019<\/dd>\n<dt>Higuchi K, Kazeto Y, Ozaki Y, Yamaguchi T, Shimada Y, Ina Y, Soma S, Sakakura Y, Goto R, Matsubara T, Nishiki I, Iwasaki Y, Yasuike M, Nakamura Y, Matsuura A, Masuma S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Masaoka T, Kobayashi T, Fujiwara A, Gen K<\/dt>\n<dd>Targeted mutagenesis of the ryanodine receptor by Platinum TALENs causes slow swimming behaviour in Pacific bluefin tuna (Thunnus orientalis)<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 9(1):13871, 2019<\/dd>\n<dt>Seirin-Lee S, Osakada F, Takeda J, Tashiro S, Kobayashi R,\u00a0<u>Yamamoto<\/u>, <u>Ochiai H<\/u><\/dt>\n<dd>Role of dynamic nuclear deformation on genomic architecture reorganization<\/dd>\n<dd><em><strong>PLoS Comput Biol.<\/strong><\/em>, 15(9):e1007289, 2019<\/dd>\n<dt>Suenaga Y, Yamamoto M, <u>Sakuma T<\/u>, Sasada M, Fukai F, Ohira M, Yamaguchi Y, <u>Yamamoto T<\/u>, Ando K, Ozaki T, Nakagawara A.<\/dt>\n<dd>TAp63 represses transcription of MYCN\/NCYM gene and its high levels of expression are associated with favorable outcome in neuroblastoma<\/dd>\n<dd><em><strong>Biochem Biophys Res Commun<\/strong><\/em>, 518(2):311-318, 2019<\/dd>\n<dt>Tanigawa S, Naganuma H, Kaku T, Era T, <u>Sakuma T<\/u>, <u>Yamamoto<\/u>, Taguchi A, Nishinakamura R<\/dt>\n<dd>Activin Is Superior to BMP7 for Efficient Maintenance of Human iPSC-Derived Nephron Progenitors<\/dd>\n<dd><em><strong>Stem Cell Reports<\/strong><\/em>, 13(2):322-337, 2019<\/dd>\n<dt>Liu D, Awazu A, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, <u>Sakamoto N<\/u><\/dt>\n<dd>Establishment of knockout adult sea urchins by using a CRISPR-Cas9 system<\/dd>\n<dd><em><strong>Development Growth &amp; Differentiation<\/strong><\/em>, 61(6):378-388, 2019<\/dd>\n<dt>Li J, Dong A, Saydaminova K, Chang HZ, Wang G, <u>Ochiai H<\/u>, <u>YamamotoT<\/u>, Pertsinidis A<\/dt>\n<dd>Single-molecule nanoscopy elucidates RNA Polymerase II transcription at single genes in live cells<\/dd>\n<dd><em><strong>Cell<\/strong><\/em>, 178(2):491-506.e28, 2019<\/dd>\n<dt>Watanabe M, Nakano K, Uchikura A, Matsunari H, Yashima S, Umeyama K, Takayanagi S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Morita S, Horii T, Hatada I, Nishinakamura R, Nakauchi H, Nagashima H<\/dt>\n<dd>Anephrogenic phenotype induced by SALL1 gene knockout in pigs<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 9(1):8016, 2019<\/dd>\n<dt>Takimoto A, Kokubu C, Watanabe H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Kondoh G, Hiraki Y and Shukunami C<\/dt>\n<dd>Differential transactivation of the upstream aggrecan enhancer regulated by PAX1\/9 depends on SOX9-driven transactivation<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 9(1):4605, 2019<\/dd>\n<dt>Kohara H, Utsugisawa T, Sakamoto C, Hirose L, Ogawa Y, Ogura H, Sugawara A, Aoki T, Iwasaki T, Asai T, Doisaki S, Okuno Y, Muramatsu H, Abe T, Kurita R, Miyamoto S, <u>Sakuma T<\/u>, Shiba M, <u>Yamamoto T<\/u>, Ohga S, Yoshida K, Ogawa S, Ito E, Kojima S, Kanno H, Tani K<\/dt>\n<dd>KLF1 Mutation E325K Induces Cell-cycle Arrest in Erythroid Cells Differentiated from Congenital Dyserythropoietic Anemia (CDA) Patient-specific Induced Pluripotent Stem Cells<\/dd>\n<dd><em><strong>Experimental Hematology<\/strong><\/em>, 73:25-37.e8, 2019<\/dd>\n<dt>Tsuda M, Ogawa S, Ooka M, Kobayashi K, Hirota K, Wakasugi M, Matsunaga T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Chikuma S, Sasanuma H, Debatisse M, Doherty AJ, Fuchs RP, Takeda S.<\/dt>\n<dd>PDIP38\/PolDIP2 controls the DNA damage tolerance pathways by increasing the relative usage of translesion DNA synthesis over template switching<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>, 14(3):e0213383, 2019<\/dd>\n<dt>Takahashi F, Igarashi K, Takimura Y and <u>Yamamoto T<\/u><\/dt>\n<dd>Elucidation of secondary alcohol metabolism in Starmerella bombicola and contribution of primary alcohol oxidase FAO1<\/dd>\n<dd><em><strong>FEMS Yeast Res<\/strong><\/em>, 19(2). pii: foz012, 2019<\/dd>\n<dt>Kazuki Y,\u00a0Kobayashi K,\u00a0Hirabayashi M,\u00a0Abe S,\u00a0Kajitani N,\u00a0Kazuki K,\u00a0Takehara S,\u00a0Takiguchi M,\u00a0Satoh D,\u00a0Kuze J,\u00a0<u>Sakuma T<\/u>,\u00a0Kaneko T,\u00a0Mashimo T,\u00a0Osamura M,\u00a0Hashimoto M,\u00a0WakatsukiR,\u00a0Hirashima R,\u00a0Fujiwara R,\u00a0Deguchi T,\u00a0Kurihara A,\u00a0Tsukazaki Y,\u00a0Senda N,\u00a0<u>Yamamoto T<\/u>,\u00a0Scheer N and\u00a0Oshimura M<\/dt>\n<dd>Humanized UGT2 and CYP3A transchromosomic rats for improved prediction of human drug metabolism<\/dd>\n<dd><em><strong>Proc Natl Acad Sci U S A<\/strong><\/em>, 116(8):3072-3081, 2019<\/dd>\n<dt>Nishitani A, Kunisawa N, Sugimura T, Sato K, Yoshida Y, Suzuki T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Asano M, Saito Y, Ohno Y and Kuramoto T<\/dt>\n<dd>Loss of HCN1 subunits causes absence epilepsy in rats<\/dd>\n<dd><em><strong>Brain Research<\/strong><\/em>, 1706:209-217, 2019<\/dd>\n<dt>Serikawa T, Kunisawa N, Shimizu S, Kato M, Alves Iha H, Kinboshi M, Nishikawa H, Shirakawa Y, Voigt B, Nakanishi S, Kuramoto T, Kaneko T, Yamamoto T, Mashimo T, Sasa M, Ohno Y<\/dt>\n<dd>Increased seizure sensitivity, emotional defects and cognitive impairment in PHD finger protein 24 (Phf24)-null rats<\/dd>\n<dd><em><strong>Behav Brain Res<\/strong><\/em>, 369:111922, 2019<\/dd>\n<dt>Harata A, Hirakawa M, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Hashimoto C<\/dt>\n<dd>Nucleotide receptor P2RY4 is required for head formation via induction and maintenance of head organizer in Xenopus laevis<\/dd>\n<dd><em><strong>Development Growth &amp; Differentiation<\/strong><\/em>, 61(2):186-197, 2019<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u5c71\u672c\u3000\u5353<\/u>\uff0c<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u5b9f\u9a13\u30b9\u30bf\u30f3\u30c0\u30fc\u30c9<\/dd>\n<dd><em><strong>\u7f8a\u571f\u793e<\/strong><\/em>,\u00a02019<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\uff0c\u570b\u4e95\u539a\u5fd7<\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u610f\u7fa9\u3068\u554f\u984c\u70b9\uff0c\u304a\u3088\u3073\u89e3\u6c7a\u7b56<\/dd>\n<dd><em><strong>\u816b\u760d\u5185\u79d1<\/strong><\/em>,\u00a024:3, 307-314\uff082019\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u790e<\/dd>\n<dd><em><strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u65b0\u6280\u8853\u3001\u7d30\u80deThe CELL(\u30cb\u30e5\u30fc\u30b5\u30a4\u30a8\u30f3\u30b9\u793e)<\/strong><\/em>,\u00a051(3):108-109\uff082019\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30a8\u30d5\u30a7\u30af\u30bf\u30fc\u96c6\u7a4d\u306b\u3088\u308b\u6b21\u4e16\u4ee3\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u65b0\u6280\u8853\u3001\u7d30\u80deThe CELL(\u30cb\u30e5\u30fc\u30b5\u30a4\u30a8\u30f3\u30b9\u793e)<\/strong><\/em>,\u00a051(3):110-113\uff082019\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u73fe\u72b6\u3068\u8ab2\u984c<\/dd>\n<dd><em><strong>\u907a\u4f1d\u5b50\u533b\u5b66\u3001\u30e1\u30c7\u30a3\u30ab\u30eb\u30c9\u30a5<\/strong><\/em>,\u00a09(1):20-24\uff082019\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u6b74\u53f2\u3068\u57fa\u790e<\/dd>\n<dd><em><strong>THE CHEMICAL TIMES\u3001\u95a2\u6771\u5316\u5b66<\/strong><\/em>,\u00a0251(1):3-6\uff082019\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u533b\u7642\u3084\u5275\u85ac\u3001\u30d0\u30a4\u30aa\u71c3\u6599\u3001\u8fb2\u755c\u7523\u7269\u306e\u54c1\u7a2e\u6539\u826f\u3084\u958b\u767a\u306b\u4e16\u754c\u304c\u6ce8\u76ee\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\uff08\u4e0b\uff09<\/dd>\n<dd><em><strong>\u79d1\u5b66\u6a5f\u5668<\/strong><\/em>,\u00a0847\uff082019\uff09<\/dd>\n<\/dl>\n<p><a name=\"2018\"><\/a><\/p>\n<h3>2018\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Kunii A, Hara Y, Takenaga M, Hattori N, Fukazawa T, Ushijima T, <u>Yamamoto T<\/u> and <u>Sakuma T<\/u><\/dt>\n<dd>Three-Component Repurposed Technology for Enhanced Expression (TREE): Highly Accumulable Transcriptional Activators via Branched Tag Arrays<\/dd>\n<dd><em><strong>The CRISPR Journal<\/strong><\/em>, 1:337-347, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30c6\u30af<\/b><\/span><\/dd>\n<dt>Miao W, Sakai K, Imamura R, Ito K, Suga H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Matsumoto K<\/dt>\n<dd>MET Activation by a Macrocyclic Peptide Agonist that Couples to Biological Responses Differently from HGF in a Context-Dependent Manner<\/dd>\n<dd><em><strong>Int. J. Mol. Sci.<\/strong><\/em>, 19(10), 2018<\/dd>\n<dt>Deguchi Y, Nishina T, Asano K, Ohmuraya M, Nakagawa Y, Nakagata N, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Araki K, Mikami T, Tanaka M and Nakano H.<\/dt>\n<dd>Generation of and characterization of anti-IL-11 antibodies using newly established Il11-deficient mice<\/dd>\n<dd><em><strong>Biochem Biophys Res. Commun.<\/strong><\/em>, 505, 453-459, 2018<\/dd>\n<dt>Suzuki M, Hayashi T, Inoue T, Agata K, Hirayama M, Suzuki M, Shigenobu S, Takeuchi T, <u>Yamamoto T<\/u>, <u>Suzuki KT<\/u><\/dt>\n<dd>Cas9 ribonucleoprotein complex allows direct and rapid analysis of coding and noncoding regions of target genes in Pleurodeles waltl development and regeneration<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>, 443, 127-136, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u65e5\u672c\u7d4c\u6e08\u65b0\u805e<\/b><\/span><\/dd>\n<dt>Tanigawa S, Islam M, Sharmin S, Naganuma H, Yoshimura Y, Haque F, Era T, Nakazato H, Nakanishi K, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Kurihara H, Taguchi A, Nishinakamura R<\/dt>\n<dd>Organoids from Nephrotic Disease-Derived iPSCs Identify Impaired NEPHRIN Localization and Slit Diaphragm Formation in Kidney Podocytes<\/dd>\n<dd><em><strong>Stem Cell Reports<\/strong><\/em>, 11, 727-740, 2018<\/dd>\n<dt>Nakade S, Mochida K, Kinii A, Nakamae K, Aida T, Tanaka K, <u>Sakamoto N<\/u>, <u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Biased genome editing using the local accumulation of DSB repair molecules system<\/dd>\n<dd><em><strong>Nature Communications<\/strong><\/em>, 9, 3270, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u6bce\u65e5\u65b0\u805e\u3001\u79d1\u5b66\u65b0\u805e\u3001\u65e5\u7d4c\u7523\u696d\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30af<\/b><\/span><\/dd>\n<dt>Yoshida M, Yokota E, <u>Sakuma T<\/u>, Yamatsuji T, Takigawa N, Ushijima T, <u>Yamamoto T<\/u>, Fukazawa T, Naomoto Y<\/dt>\n<dd>Development of an integrated CRISPRi targeting \u0394Np63 for treatment of squamous cell carcinoma<\/dd>\n<dd><em><strong>Oncotarget<\/strong><\/em>, 9, 29220-29232, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u671d\u65e5\u65b0\u805e\u3001\u65e5\u7d4c\u7523\u696d\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u5c71\u967d\u65b0\u805e\u3001\u9031\u520a\u65b0\u6f6e\u3001\u30c7\u30a4\u30ea\u30fc\u65b0\u6f6e<\/b><\/span><\/dd>\n<dt>Nakagawa Y, <u>Sakuma T<\/u>, Takeo T, Nakagata N and <u>Yamamoto T<\/u><\/dt>\n<dd>Electroporation-mediated genome editing in vitrified\/warmed mouse zygotes created by IVF via ultra-superovulation<\/dd>\n<dd><em><strong>Experimental Animals<\/strong><\/em>, 67, 535-543, 2018<\/dd>\n<dt>Saha LK, Kim S, Kang H, Akter S, Choi K, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Sasanuma H, Hirota K, Nakamura J, Honma M, Takeda S and Dertinger S<\/dt>\n<dd>Differential micronucleus frequency in isogenic human cells deficient in DNA repair pathways is a valuable indicator for evaluating genotoxic agents and their genotoxic mechanisms<\/dd>\n<dd><em><strong>Environmental and Molecular Mutagenesis<\/strong><\/em>, 59, 529-538, 2018<\/dd>\n<dt>Takashina T, Koyama T, Nohara S, Hasegawa M, Ishiguro A, Iijima K, Jun L, Shimura M, Okamura T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Ishizaka Y<\/dt>\n<dd>Identification of a cell-penetrating peptide applicable to a protein-based transcription activator-like effector expression system for cell engineering<\/dd>\n<dd><em><strong>Biomaterials<\/strong><\/em>, 173:11-21, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u65e5\u7d4c\u7523\u696d\u65b0\u805e<\/b><\/span><\/dd>\n<dt>Kim SI, Matsumoto T, Kagawa H, Nakamura M, Hirohata R, Ueno A, Ohishi M, <u>Sakuma T<\/u>, Soga T, <u>Yamamoto T<\/u> and Woltjen K<\/dt>\n<dd>Microhomology-assisted scarless genome editing in human iPSCs<\/dd>\n<dd><em><strong>Nature Communications<\/strong><\/em>, 9, 939, 2018<span style=\"color: #cc0000; font-size: small;\"><b>\u3000\u65e5\u672c\u7d4c\u6e08\u65b0\u805e\u3001\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u5316\u5b66<\/b><\/span><\/dd>\n<dt>Shukunami C, Takimoto A, Nishizaki Y, Yoshimoto Y, Tanaka S, Miura S, Watanabe H, Sakuma T, Yamamoto T, Kondoh G, Hiraki Y<\/dt>\n<dd>Scleraxis is a transcriptional activator that regulates the expression of Tenomodulin, a marker of mature tenocytes and ligamentocytes<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>, 8:3155, 2018<\/dd>\n<dt>Tanaka Y, Sone T, Higurashi N, <u>Sakuma T<\/u>, Suzuki S, Ishikawa M, <u>Yamamoto T<\/u>, Mitsui J, Tsuji H, Okano H and Hirose S<\/dt>\n<dd>Generation of D1-1 TALEN isogenic control cell line from Dravet syndrome patient iPSCs using TALEN-mediated editing of the SCN1A gene<\/dd>\n<dd><em><strong>Stem Cell Research<\/strong><\/em>, 28:100-104, 2018<\/dd>\n<dt>Kuriyama S, Tsuji T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Tanaka M<\/dt>\n<dd>PLEKHN1 promotes apoptosis by enhancing Bax-Bak hetro-oligomerization through interaction with Bid in human colon cancer<\/dd>\n<dd><em><strong>Cell Death Discovery<\/strong><\/em>,\u00a04, 11, 2018<\/dd>\n<dt>Okamoto Y, Iwasaki WM, Kugou K, Takahashi KK, Oda A, Sato K, Kobayashi W, Kawai H, Sakasai R, Takaori-Kondo A, <u>Yamamoto T<\/u>, Kanemaki MT, Taoka M, Isobe T, Kurumizaka H, Innan H, Ohta K, Ishiai M and Takata M.<\/dt>\n<dd>Replication stress induces accumulation of FANCD2 at central region of large fragile genes<\/dd>\n<dd><em><strong>Nucleic Acid Research<\/strong><\/em>,\u00a046(6):2932-2944, 2018<\/dd>\n<dt>Kinjo S, Kiyomoto M, <u>Yamamoto T<\/u>, Ikeo K and Yaguchi S<\/dt>\n<dd>HpBase: a genome database of a sea urchin, Hemicentrotus pulcherrimus<\/dd>\n<dd><em><strong>Development Growth &amp; Differentiation<\/strong><\/em>,\u00a060(3):174-182, 2018<\/dd>\n<dt><u>Sakuma T<\/u>, <u>Mochida K<\/u>, <u>Nakade S<\/u>, Ezure T, Minagawa S and <u>Yamamoto T<\/u><\/dt>\n<dd>Unexpected heterogeneity derived from Cas9 ribonucleoprotein-introduced clonal cells at the HPRT1 locus<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a023(4):255-263, 2018<\/dd>\n<dt>Sato&#8217;o Y, Hisatsune J, Yu L, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Sugai M.<\/dt>\n<dd>Tailor-made gene silencing of Staphylococcus aureus clinical isolates by CRISPR interference.<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a013(1):e0185987, 2018<\/dd>\n<dt>Kawabe Y, Komatsu S, Komatsu S, Murakami M, Ito A, <u>Sakuma T<\/u>, Nakamura T, <u>Yamamoto T<\/u> and Kamihira M<\/dt>\n<dd>Targeted knock-in of an scFv-Fc antibody gene into the hprt locus of Chinese hamster ovary cells using CRISPR\/Cas9 and CRIS-PITCh systems<\/dd>\n<dd><em><strong>Journal of Bioscience and Bioengineering<\/strong><\/em>,\u00a0125(5):599-605, 2018<\/dd>\n<dt><u>Sakane Y<\/u>, Iida M, Hasebe T, Fujii S, Buchholz DR, Ishizuya-Oka A, <u>Yamamoto T<\/u> and <u>Suzuki KT<\/u><\/dt>\n<dd>Functional analysis of thyroid hormone receptor beta in Xenopus tropicalis founders using CRISPR-Cas<\/dd>\n<dd><em><strong>Biol Open<\/strong><\/em>,\u00a07(1). pii: bio030338, 2018<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>Sakuma T<\/u>, <u>Yamamoto T<\/u><\/dt>\n<dd>Acceleration of cancer science with genome editing and related technologies<\/dd>\n<dd><em><strong>Cancer Science<\/strong><\/em>,\u00a0109(12):3679-3685, 2018<\/dd>\n<dt><u>Suzuki KT<\/u>, Sakane Y, Suzuki M, <u>Yamamoto T<\/u><\/dt>\n<dd>A Simple Knock-In System for Xenopus via Microhomology Mediated End Joining Repair<\/dd>\n<dd><em><strong>Methods Mol Biol<\/strong><\/em>,\u00a01865, 91-103, 2018<\/dd>\n<dt>Miyamoto T, Akutsu SN, Tauchi H, Kudo Y, Tashiro S, <u>Yamamoto T<\/u>, Matsuura S<\/dt>\n<dd>Exploration of genetic basis underlying individual differences in radiosensitivity within human populations using genome editing technology<\/dd>\n<dd><em><strong>Journal of Radiation Research<\/strong><\/em>,\u00a059(suppl_2):ii75-ii82, 2018<\/dd>\n<dt><u>Sakuma T<\/u>, <u>Yamamoto T<\/u><\/dt>\n<dd>Genome editing for dissecting and curing human genetic diseases<\/dd>\n<dd><em><strong>Journal of Human Genetics<\/strong><\/em>,\u00a063, 105, 2018<\/dd>\n<dt><u>Nakade A<\/u>, <u>Yamamoto T<\/u> and <u>Sakuma T<\/u><\/dt>\n<dd>Cancer induction and suppression with transcriptional control and epigenome editing technology<\/dd>\n<dd><em><strong>Journal of Human Genetics<\/strong><\/em>,\u00a063, 187\u2013194, 2018<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u672c\u539f\u7406<\/dd>\n<dd><em><strong>\u751f\u7269\u306e\u79d1\u5b66\u300c\u907a\u4f1d\u300d<\/strong><\/em>,\u00a072:6, 566-571\uff082018\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306b\u7528\u3044\u308b\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3068\u30ce\u30c3\u30af\u30a4\u30f3\u6280\u8853<\/dd>\n<dd><em><strong>\u8840\u6db2\u30d5\u30ed\u30f3\u30c6\u30a3\u30a2\u3001\u533b\u85ac\u30b8\u30e3\u30fc\u30ca\u30eb\u793e<\/strong><\/em>,\u00a028:6, 1017-1022\uff082018\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2, \u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u7dcf\u8ad6\uff1a\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u533b\u7642\u5fdc\u7528\u3092\u3081\u3056\u3059\u30b2\u30ce\u30e0\u7de8\u96c6\u3001\u5316\u5b66\u540c\u4eba<\/strong><\/em>,\u00a016-27\uff082018\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u30e1\u30c7\u30a3\u30ab\u30eb\u30fb\u30b5\u30a4\u30a8\u30f3\u30b9\u30fb\u30c0\u30a4\u30b8\u30a7\u30b9\u30c8\u3001\u30cb\u30e5\u30fc\u30b5\u30a4\u30a8\u30f3\u30b9\u793e<\/strong><\/em>,\u00a02, 398-400\uff082018\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u3082\u305f\u3089\u3059\u30d6\u30ec\u30a4\u30af\u30b9\u30eb\u30fc<\/dd>\n<dd><em><strong>\u30d5\u30a1\u30eb\u30de\u30b7\u30a2<\/strong><\/em>,\u00a054:p101\uff082018\uff09<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u533b\u7642\u3084\u5275\u85ac\u3001\u30d0\u30a4\u30aa\u71c3\u6599\u3001\u8fb2\u755c\u7523\u7269\u306e\u54c1\u7a2e\u6539\u826f\u3084\u958b\u767a\u306b\u4e16\u754c\u304c\u6ce8\u76ee\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\uff08\u4e0a\uff09<\/dd>\n<dd><em><strong>\u79d1\u5b66\u6a5f\u5668<\/strong><\/em>,\u00a0846\uff082018\uff09<\/dd>\n<\/dl>\n<p><strong>\u3010\u6559\u79d1\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u672c\u539f\u7406\u3068\u5fdc\u7528<\/dd>\n<dd>\u88f3\u83ef\u623f, 2018<\/dd>\n<\/dl>\n<p><a name=\"2017\"><\/a><\/p>\n<h3>2017\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Tsuda M, Cho K, Ooka M, Shimizu N, Watanabe R, Yasui A, Nakazawa Y, Ogi T, Harada H, Agama K, Nakamura J, Asada R, Fujiike H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Murai J, Hiraoka M, Koike K, Pommier Y, Takeda S and Hirota K<\/dt>\n<dd>ALC1\/CHD1L, a chromatin-remodeling enzyme, is required for efficient base excision repair<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a012, e0188320, 2017<\/dd>\n<dt><u>Matsushita M<\/u>, Ochiai H, <u>Suzuki KT<\/u>, <u>Hayashi S<\/u>, <u>Yamamoto T<\/u>, Awazu A and <u>Sakamoto N<\/u><\/dt>\n<dd>Dynamic changes in the interchromosomal interaction of early histone gene loci during early development of sea urchin<\/dd>\n<dd><em><strong>Journal of Cell Science<\/strong><\/em>,\u00a0130(24):4097-4107, 2017<\/dd>\n<dt>Abe S, Kobayashi K, Oji A, <u>Sakuma T<\/u>, Kazuki K, Takehara S, Nakamura K, Okada A, Tsukazaki Y, Senda N, Honma K, <u>Yamamoto T<\/u>, Ikawa M, Chiba K, Oshimura M and Kazuki Y<\/dt>\n<dd>Modification of single-nucleotide polymorphism in a fully humanized CYP3A mouse by genome editing technology<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a07, 15189, 2017<\/dd>\n<dt>Matsuzaki Y, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Saya H<\/dt>\n<dd>Establishment of pten knockout medaka with transcription activator-like effector nucleases (TALENs) as a model of PTEN deficiency disease<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a012(10):e0186878, 2017<\/dd>\n<dt>Miyamoto T, Natsuko Akutsu S, Fukumitsu A, Morino H, Masatsuna T, Hosoba K, Kawakami H, <u>Yamamoto T<\/u>, Shimizu K, Ohashi H and Matsuura S<\/dt>\n<dd>PLK1-mediated phosphorylation of WDR62\/MCPH2 ensures proper mitotic spindle orientation<\/dd>\n<dd><em><strong>Human Molecular Genetics<\/strong><\/em>,\u00a026(22):4429-4440, 2017<\/dd>\n<dt>Nakamura M, Kurungsee T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Yanaka N<\/dt>\n<dd>TALEN-mediated targeted editing of the GDE5 gene suppresses fibroblastic cell proliferation<\/dd>\n<dd><em><strong>Biosci Biotechnol Biochem<\/strong><\/em>,\u00a081(11):2164-2167, 2017<\/dd>\n<dt>Mori J, Sanoh S, Kashiwagi K, Hanada H, <u>Shigeta M<\/u>, <u>Suzuki KT<\/u>, <u>Yamamoto T<\/u>, Kotake Y, Sugihara K, Kitamura S, Kashiwagi A and Ohta S<\/dt>\n<dd>Developmental changes in drug-metabolizing enzyme expression during metamorphosis of Xenopus tropicalis<\/dd>\n<dd><em><strong>The Journal of Toxicological Sciences<\/strong><\/em>,\u00a042(5):605-613, 2017<\/dd>\n<dt>Royba E, Miyamoto T, Akutsu S, Hosoba K, Tauchi H, Kudo Y, Tashiro S, <u>Yamamoto T<\/u> and Matsuura S<\/dt>\n<dd>Evaluation of ATM heterozygous mutations underlying individual differences in radiosensitivity using genome editing in human cultured cells<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a07, 5996, 2017<\/dd>\n<dt>Kaku Y, Taguchi A, Tanigawa S, Haque F, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Nishinakamura R<\/dt>\n<dd>PAX2 is dispensable for in vitro nephron formation from human induced pluripotent stem cells<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a07, 4554, 2017<\/dd>\n<dt>Oike A, Kodama M, Yasumasu S, <u>Yamamoto T<\/u>, Nakamura Y, Ito E and Nakamura M<\/dt>\n<dd>Participation of androgen and its receptor in sex determination of an amphibian species<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a012(6):e0178067, 2017<\/dd>\n<dt>Nakagawa Y, <u>Sakuma T<\/u>, Nishimichi N, Yokosaki Y, Takeo T, Nakagata N and <u>Yamamoto T<\/u><\/dt>\n<dd>Culture time of vitrified\/warmed zygotes before microinjection affects the production efficiency of CRISPR-Cas9-mediated knock-in mice<\/dd>\n<dd><em><strong>Biology Open<\/strong><\/em>,\u00a06(5):706-713, 2017<\/dd>\n<dt><u>Nakamae K<\/u>, Nishimura Y, <u>Takenaga M<\/u>, <u>Nakade S<\/u>, <u>Sakamoto N<\/u>, Ide H, <u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Establishment of expanded and streamlined pipeline of PITCh knock-in \u2013 a web-based design tool for MMEJ-mediated gene knock-in, PITCh designer, and the variations of PITCh, PITCh-TG and PITCh-KIKO<\/dd>\n<dd><em><strong>Bioengineered<\/strong><\/em>,\u00a08(3):302-308, 2017<\/dd>\n<dt>Yoshida K, Nakahata A, Treen N, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Sasakura Y<\/dt>\n<dd>Hox-mediated endodermal identity patterns the pharyngeal muscle formation in the chordate pharynx<\/dd>\n<dd><em><strong>Development<\/strong><\/em>,\u00a0144(9):1629-1634, 2017<\/dd>\n<dt>Kameda T, Isami S, Togashi Y, Nishimori H, <u>Sakamoto N<\/u> and Awazu A<\/dt>\n<dd>The 1-Particle-per-k-Nucleotides (1PkN) Elastic Network Model of DNA Dynamics with Sequence-Dependent Geometry<\/dd>\n<dd><em><strong>Front Physiol<\/strong><\/em>,\u00a08:103, 2017<\/dd>\n<dt>Takayama K, Igai K, Hagihara Y, Hashimoto R, Hanawa M, <u>Sakuma T<\/u>, Tachibana M, Sakurai F, <u>Yamamoto T<\/u> and Mizuguchi H<\/dt>\n<dd>Highly efficient biallelic genome editing of human ES\/iPS cells Using a CRISPR\/Cas9 or TALEN system<\/dd>\n<dd><em><strong>Nucleic Acid Research<\/strong><\/em>,\u00a045(9):5198-5207, 2017<\/dd>\n<dt>Mizutani O, Arazoe T, Toshida K, Hayashi R, Ohsato S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Kuwata S and Yamada O<\/dt>\n<dd>Detailed analysis of targeted gene mutations caused by the Platinum-Fungal TALENs in Aspergillus oryzae RIB40 strain and a ligD disruptant<\/dd>\n<dd><em><strong>Journal of Bioscience and Bioengineering<\/strong><\/em>,\u00a0123:287-293, 2017<\/dd>\n<dt>Yoshida\u3000K, Hozumi A, Treen N, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Shirae-Kurabayashi M and Sasakura Y<\/dt>\n<dd>Germ cell regeneration-mediated, enhanced mutagenesis in the ascidian Ciona intestinalis<br \/>\nreveals flexible germ cell formation from different somatic cells<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>,\u00a0423:111-125, 2017<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Magic wands of CRISPR &#8211; lots of choices for gene knock-in<\/dd>\n<dd><em><strong>Cell Biology &amp; Toxicology<\/strong><\/em>,\u00a033:501-505, 2017<\/dd>\n<dt>Takata N, Sakakura E, <u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Genetic Tools for Self-Organizing Culture of Mouse Embryonic Stem Cells via Small Regulatory RNA-Mediated Technologies, CRISPR\/Cas9, and Inducible RNAi<\/dd>\n<dd><em><strong>RNAi and Small Regulatory RNAs in Stem Cells, Methods Mol Biol.<\/strong><\/em>,\u00a01622:269-292<\/dd>\n<dt><u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Current overview of TALEN construction systems<\/dd>\n<dd><em><strong>Genome Editing in Animals, Methods Mol Biol.<\/strong><\/em>,\u00a01630:25-36<\/dd>\n<dt><u>Sakane Y<\/u>, <u>Suzuki KT<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>A Simple Protocol for Loss-of-Function Analysis in Xenopus tropicalis founders using the CRISPR-Cas System<\/dd>\n<dd><em><strong>Genome Editing in Animals, Methods Mol Biol.<\/strong><\/em>,\u00a01630:189-203<\/dd>\n<dt>Ochiai H and <u>Yamamoto T<\/u><\/dt>\n<dd>Construction and Evaluation of Zinc Finger Nucleases<\/dd>\n<dd><em><strong>Genome Editing in Animals, Methods Mol Biol.<\/strong><\/em>,\u00a01630:1-24<\/dd>\n<dt><u>Nakade S<\/u>, <u>Yamamoto T<\/u> and <u>Sakuma T<\/u><\/dt>\n<dd>Cas9, Cpf1 and C2c1\/2\/3\u2015What&#8217;s next?<\/dd>\n<dd><em><strong>Bioengineered<\/strong><\/em>,\u00a08:265-273, 2017<\/dd>\n<dt><u>Sakuma T<\/u>, Sakamoto T and <u>Yamamoto T<\/u><\/dt>\n<dd>All-in-One CRISPR-Cas9\/FokI-dCas9 Vector-Mediated Multiplex Genome Engineering in Cultured Cells<\/dd>\n<dd><em><strong>In Vitro Mutagenesis, Methods Mol Biol.<\/strong><\/em>,\u00a01498:41-56, 2017<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u6700\u65b0\u65b9\u6cd5\u8ad6<\/dd>\n<dd><em><strong>DNA\u9451\u5b9a<\/strong><\/em>,\u00a09:1-8\uff082017\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u533b\u5b66\u5206\u91ce\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u73fe\u72b6\u3068\u5c06\u6765\u5c55\u671b<\/dd>\n<dd><em><strong>CLINICAL CALCIUM<\/strong><\/em>,\u00a027:1788-1793\uff082017\uff09<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u672c\u539f\u7406<\/dd>\n<dd><em><strong>CLINICAL CALCIUM<\/strong><\/em>,\u00a027:1638-1644\uff082017\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u4e2d\u51fa\u7fd4\u592a<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30a8\u30d4\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u30a8\u30d4\u30b8\u30a7\u30cd\u30c6\u30a3\u30af\u30b9\u5b9f\u9a13\u30b9\u30bf\u30f3\u30c0\u30fc\u30c9\u300d\uff08\u725b\u5cf6\u4fca\u548c, \u771e\u8c9d\u6d0b\u4e00, \u5869\u898b\u6625\u5f66\u7de8\uff09<\/strong><\/em>,\u00a0\u7f8a\u571f\u793e, pp345-352\uff082017\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001\u9ad8\u7530 \u671b<\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u6700\u65b0\u52d5\u5411<\/dd>\n<dd><em><strong>\u30ca\u30ce\u30d0\u30a4\u30aa\u30fb\u30e1\u30c7\u30a3\u30b7\u30f3\uff0d\u7d30\u80de\u6838\u5185\u53cd\u5fdc\u3068\u30b2\u30ce\u30e0\u7de8\u96c6\uff08\u5b87\u7406\u9808\u6052\u96c4\u7de8\uff09<\/strong><\/em>,\u00a0\u8fd1\u4ee3\u79d1\u5b66\u793e, pp7-12 (2017)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u6b74\u53f2\u3068\u73fe\u72b6<\/dd>\n<dd><em><strong>\u30ca\u30ce\u30d0\u30a4\u30aa\u30fb\u30e1\u30c7\u30a3\u30b7\u30f3\uff0d\u7d30\u80de\u6838\u5185\u53cd\u5fdc\u3068\u30b2\u30ce\u30e0\u7de8\u96c6\uff08\u5b87\u7406\u9808\u6052\u96c4\u7de8\uff09<\/strong><\/em>,\u00a0\u8fd1\u4ee3\u79d1\u5b66\u793e, pp135-150 (2017)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u300cCRISPR-Cas9\u300d\u3068\u306f\u3069\u306e\u3088\u3046\u306a\u6280\u8853\u304b\uff1f<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66<\/strong><\/em>,\u00a035:2199, 2017<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u306e\u9032\u5c55<\/dd>\n<dd><em><strong>\u65e5\u672c\u81e8\u5e8a<\/strong><\/em>,\u00a075:778-782, 2017<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u9032\u5c55\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u73fe\u4ee3\u5316\u5b66<\/strong><\/em>,\u00a0551:18-22, 2017<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u3068\u306f\u3069\u3093\u306a\u6280\u8853\u306a\u306e\u304b<\/dd>\n<dd><em><strong>\u65e5\u672c\u5316\u5b66\u4f1a\u30d0\u30a4\u30aa\u30c6\u30af\u30ce\u30ed\u30b8\u30fc\u90e8\u4f1a\u30cb\u30e5\u30fc\u30b9\u30ec\u30bf\u30fc<\/strong><\/em>,\u00a020(2):3-6, 2017<\/dd>\n<\/dl>\n<p><a name=\"2016\"><\/a><\/p>\n<h3>2016\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Aida T, <u>Nakade S<\/u>, <u>Sakuma T<\/u>, Izu Y, <u>Oishi A<\/u>, <u>Mochida K<\/u>, Ishikubo H, Usami T, Aizawa H, <u>Yamamoto T<\/u> and Tanaka K<\/dt>\n<dd>Gene cassette knock-in in mammalian cells and zygotes by enhanced MMEJ<\/dd>\n<dd><em><strong>BMC Genomics<\/strong><\/em>,\u00a017, 979, 2016<\/dd>\n<dt>Toyonaga K, Torigoe S, Motomura Y, Kamichi T, Hayashi JM, Morita YS, Noguchi N, Chuma Y, Kiyohara H, Matsuo K, Tanaka H, Nakagawa Y, <u>Sakuma T<\/u>, Ohmuraya M, <u>Yamamoto T<\/u>, Umemura M, Matsuzaki G, Yoshikai Y, Yano I, Miyamoto T, Yamasaki S<\/dt>\n<dd>C-Type Lectin Receptor DCAR Recognizes Mycobacterial Phosphatidyl-Inositol Mannosides to Promote a Th1 Response during Infection<\/dd>\n<dd><em><strong>Immunity<\/strong><\/em>,\u00a045(6): 1245-1257, 2016<\/dd>\n<dt>Sasakura Y, Ogura Y, Treen N, Yokomori R, Park S-J, Nakai K, Saiga H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Fujiwara S, Yoshida K<\/dt>\n<dd>Transcriptional regulation of a horizontally transferred gene from bacterium to chordate<\/dd>\n<dd><em><strong>Proceedings B<\/strong><\/em>,\u00a0283(1845), 2016<\/dd>\n<dt>Tochio N, Umehara K, Uewaki J, Flechsig H, Kondo M, Dewa T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Saitoh T, Togashi Y and Tate SI<\/dt>\n<dd>Non-RVD mutations that enhance the dynamics of the TAL repeat array along the superhelical axis improve TALEN genome editing efficacy<\/dd>\n<dd><em><strong>Sci Rep<\/strong><\/em>,\u00a06, 37887, 2016<\/dd>\n<dt><u>Suzuki KT<\/u>, <u>Suzuki M<\/u>, <u>Shigeta M<\/u>, Fortriede JD, Takahashi S, Mawaribuchi S, <u>Yamamoto T<\/u>, Taira M and Fukui A<\/dt>\n<dd>Clustered Xenopus keratin genes: A genomic, transcriptomic, and proteomic analysis<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>,\u00a0426(2):384-392<\/dd>\n<dt><u>Sakuma T<\/u>, Masaki K, Abe-Chayama H, <u>Mochida K<\/u>, <u>Yamamoto T<\/u> and Chayama K<\/dt>\n<dd>Highly multiplexed CRISPR-Cas9-nuclease and Cas9-nickase vectors for inactivation of hepatitis B virus<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a021, 1253-1262, 2016<\/dd>\n<dt>Sato K, Oiwa R, Kumita W, Henry R, <u>Sakuma T<\/u>, Ito R, Nozu R, Inoue T, Katano I, Sato K, Okahara N, Okahara J, Yamamoto M, Hanazawa K, Kawakami T, Kametani Y, Suzuki R, Takahashi T, Weinstein E, <u>Yamamoto T<\/u>, Sakakibara Y, Habu S, Hata J, Okano H and Sasaki E<\/dt>\n<dd>Non-human primate model of severe combined immunodeficiency using highly efficient genome editing<\/dd>\n<dd><em><strong>Cell Stem Cell<\/strong><\/em>,\u00a019, 127-138, 2016<\/dd>\n<dt>Yabe T, Hoshijima K, <u>Yamamoto T<\/u> and Takada S<\/dt>\n<dd>Mesp quadruple zebrafish mutant reveals different roles of mesp genes in somite segmentation between mouse and zebrafish<\/dd>\n<dd><em><strong>Development<\/strong><\/em>,\u00a0143, 2842-2852, 2016<\/dd>\n<dt>Sasaki T, Hanisch F-G, Deutzmann R, Sakai LY, <u>Sakuma T<\/u>, Miyamoto T, <u>Yamamoto T<\/u>, Hannappel E, Chu M-L, Lanig H and von der Mark K<\/dt>\n<dd>Functional consequence of fibulin-4 missense mutations associated with vascular abnormalities and cutis laxa<\/dd>\n<dd><em><strong>Matrix Biology<\/strong><\/em>,\u00a056, 132-149, 2016<\/dd>\n<dt>Nakagawa Y, <u>Sakuma T<\/u>, Nishimichi N, Yokosaki Y, Yanaka N, Takeo T, Nakagata N, and <u>Yamamoto T<\/u><\/dt>\n<dd>Ultra-superovulation for the CRISPR-Cas9-mediated production of gene-knockout,single-amino-acid-substituted, and floxed mice<\/dd>\n<dd><em><strong>Biol Open<\/strong><\/em>, 5, 1142-1148, 2016<\/dd>\n<dt>Nii T, Kohara H, Marumoto T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Tani K<\/dt>\n<dd>Single-Cell-State Culture of Human Pluripotent Stem Cells Increases Transfection Efficiency<\/dd>\n<dd><em><strong>Biores Open Access<\/strong><\/em>,\u00a05, 127-136, 2016<\/dd>\n<dt><u>Shigeta M<\/u>, <u>Sakane Y<\/u>, Iida M, <u>Suzuki M<\/u>, Kashiwagi K, Kashiwagi A, Fujii S, <u>Yamamoto T<\/u> and <u>Suzuki KT<\/u><\/dt>\n<dd>Rapid and efficient analysis of gene function using CRISPR-Cas9 in Xenopus tropicalis founders<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>, 21, 755-771, 2016<\/dd>\n<dt>Ichiyanagi N, Fujimori K, Yano M, Ishihara-Fujisaki C, Sone T, Akiyama T, Okada Y, Akamatsu W, Matsumoto T, Ishikawa M, Nishimoto Y, Ishihara Y, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Tsuiji H, Suzuki N, Warita H, Aoki M and Okano H<\/dt>\n<dd>Establishment of In Vitro FUS-Associated Familial Amyotrophic Lateral Sclerosis Model Using Human Induced Pluripotent Stem Cells<\/dd>\n<dd><em><strong>Stem Cell Reports<\/strong><\/em>,\u00a06, 496-510, 2016<\/dd>\n<dt>Nishitani A, Tanaka M, Shimizu S, Yokoe M, Yoshida Y, Suzuki T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Kuwamura M, Takemoto S, Ohono Y and Kuramoto T<\/dt>\n<dd>Involvement of aspartoacylase in tremor expression in rats<\/dd>\n<dd><em><strong>Experimental Animals<\/strong><\/em>,\u00a065, 293-301, 2016<\/dd>\n<dt>Banno K, Omori S, Hirata K, Nawa N, Nakagawa N, Nishimura K, Ohtaka M, Nakanishi M, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Toki T, Ito E, Yamamoto T, Kokubu C, Takeda J, Taniguchi H, Arahori H, Wada K, Kitabatake Y and Ozono K<\/dt>\n<dd>Systematic Cellular Disease Models Reveal Synergistic Interaction of Trisomy 21 and GATA1 Mutations in Hematopoietic Abnormalities<\/dd>\n<dd><em><strong>Cell Reports<\/strong><\/em>,\u00a015, 1228-1241, 2016<\/dd>\n<dt>Woltjen K, <u>Yamamoto T<\/u>, Kokubu C and Takeda J<\/dt>\n<dd>Report on the Conference on Transposition and Genome Engineering 2015 (TGE 2015): Advancing cutting-edge genomics technology in the ancient city of Nara<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>, 21, 392-395, 2016<\/dd>\n<dt><u>Takemoto A<\/u>, Miyamoto T, Simono F, Kurogi N, Shirae-Kurabayashi M, Awazu A, <u>Suzuki KT<\/u>, <u>Yamamoto T<\/u> and <u>Sakamoto N<\/u><\/dt>\n<dd>Cilia play a role in breaking left\u2013right symmetry of the sea urchin embryo<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a021, 568-578, 2016<\/dd>\n<dt>Nakahara Y, Muto A, Hirabayashi R, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Kume S and Kikuchi Y<\/dt>\n<dd>Temporal effects of Notch signaling and potential cooperation with multiple downstream effectors on adenohypophysis cell specification in zebrafish<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a021, 492-504, 2016<\/dd>\n<dt>Marsan E, Ishida S, Schramm A, Weckhuysen S, Muraca G, Lecas S, Liang N, Treins C, Pende M, Roussel D, Quyen MLV, Mashimo T, Kaneko T, <u>Yamamoto T<\/u>, <u>Sakuma T<\/u>, Mahon S, Miles R, Leguern E, Charpier S and Baulac S<\/dt>\n<dd>Depdc5 knockout rat: a novel model of mTORopathy<\/dd>\n<dd><em><strong>Neurobiology of Disease<\/strong><\/em>,\u00a089, 180-189, 2016<\/dd>\n<dt>Takata N, Sakakura E, Kasukawa T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Sasai Y<\/dt>\n<dd>Establishment of functional genomics pipeline in epiblast-like tissue by combining transcriptomic analysis and gene knock-down\/-in\/-out using RNAi and CRISPR\/Cas9<\/dd>\n<dd><em><strong>Human Gene Therapy<\/strong><\/em>,\u00a027, 436-450, 2016<\/dd>\n<dt>Guo L, Yamashita H, Kou I, Takimoto A, Meguro-Horike M, <u>Sakuma T<\/u>, Miura S, Adachi T, <u>Yamamoto T<\/u>, Ikegawa S, Hiraki Y and Shukunami C<\/dt>\n<dd>Functional investigation of a non-coding variant associated with adolescent idiopathic scoliosis in zebrafish: elevated expression of the ladybird homeobox gene causes body axis deformation<\/dd>\n<dd><em><strong>PLoS Genetics<\/strong><\/em>,\u00a012, e1005802, 2016 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt><u>Suzuki M<\/u>, Takagi C, Miura S, <u>Sakane Y<\/u>, Suzuki M, <u>Sakuma T<\/u>, <u>Sakamoto N<\/u>, Endo T, Kamei Y, Sato Y, Kimura H, <u>Yamamoto T<\/u>, Ueno N and <u>Suzuk KT<\/u><\/dt>\n<dd>In vivo tracking of histone H3 lysine 9 acetylation in Xenopus laevis during tail regeneration<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a021, 358-369, 2016\u3000<span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt><u>Sakuma T<\/u>, <u>Nakade S<\/u>, <u>Sakane Y<\/u>, <u>Suzuki KT<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>MMEJ-assisted gene knock-in using TALENs and CRISPR-Cas9 with the PITCh systems<\/dd>\n<dd><em><strong>Nature Protocols<\/strong><\/em>,\u00a011, 118\u2013133, 2016 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Sharmin S, Taguchi A, Kaku Y, Yoshimura Y, Ohmori T, <u>Sakuma T<\/u>, Mukoyama M, <u>Yamamoto T<\/u>, Kurihara H and Nishinakamura R<\/dt>\n<dd>Human iPS cell-derived podocytes expressing typical molecular signatures maturate upon transplantation<\/dd>\n<dd><em><strong>Journal of the American Society of Nephrology<\/strong><\/em>,\u00a027, 1778-1791, 2016 <span style=\"color: #cc0000; font-size: small;\"><b>\u6bce\u65e5\u65b0\u805e<\/b><\/span><\/dd>\n<dt>Rao S, Fujimura T, Matsunari H, <u>Sakuma T<\/u>, Nakano K, Watanabe M, Asano Y, Kitagawa E, <u>Yamamoto T<\/u> and Nagashima H.<\/dt>\n<dd>Efficient modification of myostatin gene in porcine somatic cells and generation of knockout piglets.<\/dd>\n<dd><em><strong>Molecular Reproduction and Development<\/strong><\/em>,\u00a083:61\u201370, 2016\u3000<span style=\"color: #cc0000; font-size: small;\"><b>\u8aad\u58f2\u65b0\u805e\u3001Yahoo\u30cb\u30e5\u30fc\u30b9<\/b><\/span><\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u672c\u539f\u7406<\/dd>\n<dd><em><strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u5165\u9580\uff08\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u88f3\u83ef\u623f\uff082016\uff09<\/dd>\n<dt><u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u6d77\u7523\u7121\u810a\u690e\u52d5\u7269\u3067\u306e\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u5229\u7528<\/dd>\n<dd><em><strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u5165\u9580\uff08\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u88f3\u83ef\u623f\uff082016\uff09<\/dd>\n<dt><u>\u9234\u6728\u8ce2\u4e00<\/u><\/dt>\n<dd>\u4e21\u751f\u985e\u3067\u306e\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u5229\u7528<\/dd>\n<dd><em><strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u5165\u9580\uff08\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u88f3\u83ef\u623f\uff082016\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u4e2d\u51fa\u7fd4\u592a<\/u><\/dt>\n<dd>\u65b0\u898f\u30b2\u30ce\u30e0\u7de8\u96c6\u30c4\u30fc\u30eb\u306e\u958b\u767a\u52d5\u5411<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300cAll About\u30b2\u30ce\u30e0\u7de8\u96c6\u300d\uff08\u771f\u4e0b\u77e5\u58eb\u3001\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u7f8a\u571f\u793e\uff082016\uff09<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u4e2d\u51fa\u7fd4\u592a<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u3055\u307e\u3056\u307e\u306a\u907a\u4f1d\u5b50\u30ce\u30c3\u30af\u30a4\u30f3\u30b7\u30b9\u30c6\u30e0<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300cAll About\u30b2\u30ce\u30e0\u7de8\u96c6\u300d\uff08\u771f\u4e0b\u77e5\u58eb\u3001\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u7f8a\u571f\u793e\uff082016\uff09<\/dd>\n<dt><u>\u9234\u6728\u8ce2\u4e00<\/u><\/dt>\n<dd>\u4e21\u751f\u985e\u306e\u30b2\u30ce\u30e0\u7de8\u96c6<\/dd>\n<dd><em><strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300cAll About\u30b2\u30ce\u30e0\u7de8\u96c6\u300d\uff08\u771f\u4e0b\u77e5\u58eb\u3001\u5c71\u672c \u5353\u7de8\uff09<\/strong><\/em>,\u00a0\u7f8a\u571f\u793e\uff082016\uff09<\/dd>\n<dt><u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u5de6\u53f3\u76f8\u79f0\u306e\u30d7\u30eb\u30c6\u30a6\u30b9\u5e7c\u751f\u304b\u3089\u4e94\u653e\u5c04\u76f8\u79f0\u306e\u30a6\u30cb\u3078<\/dd>\n<dd><em><strong>\u751f\u7269\u79d1\u5b66<\/strong><\/em>,\u00a067:133-138, 2016<\/dd>\n<dt><u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Engineering Customized TALENs Using the Platinum Gate TALEN Kit<\/dd>\n<dd><em><strong>TALENs: Methods and Protocols, Methods Mol Biol.<\/strong><\/em>,\u00a01338:61-70, 2016<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u790e\u3068\u5fdc\u7528<\/dd>\n<dd><em><strong>\u81e8\u5e8a\u8840\u6db2<\/strong><\/em>,\u00a057:1869-1873, 2016<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u306e\u539f\u7406\u3068\u5fdc\u7528<\/dd>\n<dd><em><strong>\u5927\u962a\u5927\u5b66\u533b\u5b66\u90e8\u5b66\u53cb\u4f1a\u4f1a\u8a8c<\/strong><\/em>,\u00a036:65-68, 2016<\/dd>\n<\/dl>\n<p><strong>\u3010\u6559\u79d1\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u52d5\u7269\u306e\u304b\u3089\u3060\u4f5c\u308a<\/dd>\n<dd><em><strong>\u57fa\u790e\u751f\u7269\u79d1\u5b66\uff08\u9ad8\u6a4b\u7d14\u592b\u7de8\uff09<\/strong><\/em>,\u00a0\u57f9\u98a8\u9928, pp84-91\uff082016\uff09<\/dd>\n<dt><u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>DNA\u306e\u69cb\u9020\u3068\u8907\u88fd\u3001<\/dd>\n<dd><em><strong>\u57fa\u790e\u751f\u7269\u79d1\u5b66\uff08\u9ad8\u6a4b\u7d14\u592b\u7de8\uff09<\/strong><\/em>,\u00a0\u57f9\u98a8\u9928, pp67-74\uff082016\uff09<\/dd>\n<\/dl>\n<p><strong>\u3010\u7279\u8a31\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd><\/dd>\n<dd>\u690d\u7269\u7d30\u80de\u3078\u306e\u30bf\u30f3\u30d1\u30af\u8cea\u306e\u5c0e\u5165\u6cd5\uff08\u7406\u5316\u5b66\u7814\u7a76\u6240\u3001\u5b87\u90fd\u5bae\u5927\u5b66\u3001\u7b51\u6ce2\u5927\u5b66\u3068\u306e\u5171\u540c\u51fa\u9858\uff09\u3001\u7279\u98582016-009207 (2016)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2015\"><\/a><\/p>\n<h3>2015\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Ninagawa S, Okada T, Sumitomo Y, Horimoto S, Sugimoto T, Ishikawa T, Takeda S, <u>Yamamoto T<\/u>, Suzuki T, Kamiya Y, Kato K and Mori K<\/dt>\n<dd>Forcible destruction of severely misfolded mammalian glycoproteins by the non-glycoprotein ERAD pathway<\/dd>\n<dd><em><strong>Journal of Cell Biology<\/strong><\/em>,\u00a0211: 775-784, 2015<\/dd>\n<dt>Hoa NN, Akagawa R, Yamasaki T, Hirota K, Sasa K, Natsume T, Kobayashi J, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Komatsu K, Kanemaki M, Pommier Y, Takeda S and Sasanuma H<\/dt>\n<dd>Relative contribution of four nucleases, CtIP, Dna2, Exo1 and Mre11 to the initial step of double-strand break repair by homologous DNA recombination in the both chicken DT40 and human TK6 cell lines<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a020:1059\u20131076, 2015<\/dd>\n<dt>Isami S, <u>Sakamoto N<\/u>, Nishimori H and Awazu A<\/dt>\n<dd>Simple Elastic Network Models for Exhaustive Analysis of Long Double-Stranded DNA Dynamics with Sequence Geometry Dependence<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a0211(4): 775-784, 2015<\/dd>\n<dt>Miyamoto K, <u>Suzuki K<\/u>, <u>Suzuki M<\/u>, <u>Sakane Y<\/u>, <u>Sakuma T<\/u>, Herberg S, Simeone A, Simpson D, Jullien J, <u>Yamamoto T<\/u> and Gurdon JB<\/dt>\n<dd>The Expression of TALEN before Fertilization Provides a Rapid Knock-out Phenotype in Xenopus laevis Founder Embryos<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a010(11):e0142946, 2015\u3000<span style=\"color: #cc0000; font-size: small;\"><b>\u8aad\u58f2\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt><u>Sakuma T<\/u>, <u>Takenaga M<\/u>, Kawabe Y, Nakamura T, Kamihira M and <u>Yamamoto T<\/u><\/dt>\n<dd>Homologous recombination-independent large gene cassette knock-in in CHO cells using TALEN and MMEJ-directed donor plasmid<\/dd>\n<dd><em><strong>International Journal of Molecular Sciences<\/strong><\/em>,\u00a016: 23849-23866, 2015<\/dd>\n<dt>Sasaki K, Yokobayashi S, Nakamura T, Okamoto I, Yabuta Y, Kurimoto K, Ohta H, Moritoki Y, Iwatani C, Tsuchiya H, Nakamura S, Sekiguchi K, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Mori T, Woltjen K, Nakagawa M, Yamamoto T, Takahashi K, Yamanaka S and Saitou M<\/dt>\n<dd>Robust in vitro induction of human germ cell fate from pluripotent stem cells.<\/dd>\n<dd><em><strong>Cell Stem Cell<\/strong><\/em>,\u00a017: 178-194, 2015<\/dd>\n<dt>Ochiai H, Sugawara T and <u>Yamamoto T<\/u><\/dt>\n<dd>Simultaneous live imaging of the transcription and nuclear position of specific genes.<\/dd>\n<dd><em><strong>Nucleic Acid Research<\/strong><\/em>,\u00a0doi: 10.1093\/nar\/gkv624, 2015\u3000<span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001Eurekalert!\u3001Alphagalileo\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Keka I, Mohiuddin M, Rahman MM, Maede Y, <u>Sakuma T<\/u>, Honma M, <u>Yamamoto T<\/u>, Takeda S and Sasanuma H<\/dt>\n<dd>Smarcal1 Promotes Double-Strand-Break Repair by Nonhomologous End-Joining<\/dd>\n<dd><em><strong>Nucleic Acid Research<\/strong><\/em>,\u00a043: 6359-6372, 2015\u3000<span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Iizuka H, Kagoya Y, Kataoka K, Yoshimi A, Miyauchi M, Taoka K, Kumano K, <u>Yamamoto T<\/u>, Hotta A, Arai S and Kurokawa M.<\/dt>\n<dd>Targeted gene correction of RUNX1 in induced pluripotent stem cells derived from familial platelet disorder with propensity to myeloid malignancy restores normal megakaryopoiesis.<\/dd>\n<dd><em><strong>Experimental Hematology<\/strong><\/em>,\u00a043: 849-857, 2015<\/dd>\n<dt>Fujiwara M, Fujimura K, Obata S, Yanagibashi R, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Suzuki ST<\/dt>\n<dd>Epithelial DLD-1 cells with disrupted E-cadherin gene retain the ability to form cell junctions<\/dd>\n<dd><em><strong>Cell Structure and Function<\/strong><\/em>,\u00a040: 79-94, 2015<\/dd>\n<dt>Sato T, <u>Sakuma T<\/u>, Yokonishi T, Katagiri K, Ogonuki N, Ogura A, <u>Yamamoto T<\/u> and Ogawa T<\/dt>\n<dd>Genome editing in mouse spermatogonial stem cell lines using TALEN and double-nicking CRISPR\/Cas9 systems<\/dd>\n<dd><em><strong>Stem Cell Reports<\/strong><\/em>,\u00a05: 75-82, 2015<\/dd>\n<dt>Fujiwara M, Nagatomo A, Tsuda M, Obata S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Suzuki ST<\/dt>\n<dd>Desmocollin-2 alone forms functional desmosomal plaques, with the plaque formation requiring the juxtamembrane region and plakophilins<\/dd>\n<dd><em><strong>Journal of Biochemistry<\/strong><\/em>,\u00a0158: 339-353<\/dd>\n<dt>Hara S, Tamano M, Yamashita S, Kato T, Saito T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Inui M and Takada S<\/dt>\n<dd>Generation of mutant mice via the CRISPR\/Cas9 system using FokI-dCas9<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a05: 11221, 2015<\/dd>\n<dt>Nakagawa Y, <u>Sakuma T<\/u>, Sakamoto T, Ohmuraya M, Nakagata N and <u>Yamamoto T<\/u><\/dt>\n<dd>Production of knockout mice by DNA microinjection of various CRISPR\/Cas9 vectors into freeze-thawed fertilized oocytes<\/dd>\n<dd><em><strong>BMC Biotechnology<\/strong><\/em>,\u00a015: 33, 2015<\/dd>\n<dt>Aida T, Chiyo K, Usami T, Ishikubo H, Imahashi R, Wada Y, Tanaka K, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Tanaka K<\/dt>\n<dd>Cloning-free CRISPR\/Cas system facilitates functional cassette knockin in mice<\/dd>\n<dd><em><strong>Genome Biology<\/strong><\/em>,\u00a016: 87, 2015 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001Genome Biology\u306eReseach Highlight\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt><u>Nakade S<\/u>, <u>Sakuma T<\/u>, <u>Sakane Y<\/u>, <u>Hara Y<\/u>, Kurabayashi A, Kashiwagi K, Kashiwagi A, <u>Yamamoto T<\/u> and Obara M<\/dt>\n<dd>Homeolog-specific targeted mutagenesis in Xenopus laevis using TALENs<\/dd>\n<dd><em><strong>In Vitro Cellular &amp; Developmental Biology &#8211; Animal<\/strong><\/em>,\u00a051: 879-884, 2015<\/dd>\n<dt>Kawai N, Ogura Y, Ikuta T, Saiga H, Hamada M, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Satoh N and Sasakura Y<\/dt>\n<dd>Hox10-regulated endodermal cell migration is essential for development of the ascidian intestine<\/dd>\n<dd><em><strong>Developmental Biology<\/strong><\/em>,\u00a0403: 43-56, 2015<\/dd>\n<dt>Uemura N, Koike M, Ansai S, Kinoshita M, Ishikawa-Fujiwara T, Matsui H, Naruse K, <u>Sakamoto N<\/u>, Uchiyama Y, Todo T, Takeda S, Yamakado H and Takahashi R<\/dt>\n<dd>Viable neuronopathic Gaucher disease model in Medaka (Oryzias latipes) displays axonal accumulation of alpha-synuclein<\/dd>\n<dd><em><strong>PLoS Genetics<\/strong><\/em>,\u00a011: e1005065, 2015<\/dd>\n<dt>Ebina H, Kanemura Y, Misawa N, <u>Sakuma T<\/u>, Kobayashi T, <u>Yamamoto T<\/u> and Koyanagi Y<\/dt>\n<dd>A high excision potential of TALENs for integrated DNA of HIV-based lentiviral vector<\/dd>\n<dd><em><strong>PLoS One<\/strong><\/em>,\u00a010: e0120047, 2015<\/dd>\n<dt>Hisano Y, <u>Sakuma T<\/u>, <u>Nakade S<\/u>, Ohga R, Ota S, Okamoto H, <u>Yamamoto T<\/u> and Kawahara A<\/dt>\n<dd>Precise in-frame integration of exogenous DNA mediated by CRISPR\/Cas9 system in zebrafish<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a05: 8841, 2015 <span style=\"color: #cc0000; font-size: small;\"><b>\u671d\u65e5\u65b0\u805e\u3001\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u5c71\u68a8\u65e5\u65e5\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt>Arazoe T, Ogawa T, Miyoshi K, Yamato T, Ohsato S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Arie T and Kuwata S<\/dt>\n<dd>Tailor-made TALEN system for highly efficient targeted gene replacement in the rice blast fungus<\/dd>\n<dd><em><strong>Biotechnology and Bioengineering<\/strong><\/em>, 112: 1335-1342, 2015 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Miyamoto T, Hosoba K, Ochiai H, Royba E, Izumi H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Dynlacht BD and Matsuura S<\/dt>\n<dd>The microtubule depolymerizing activity of a mitotic kinesin protein KIF2A drives primary cilia disassembly coupled with cell proliferation<\/dd>\n<dd><em><strong>Cell Reports<\/strong><\/em>,\u00a0doi:10.1016\/j.celrep.2015.01.003, 2015<\/dd>\n<dt>Choi J, <u>Suzuki KT<\/u>, <u>Sakuma T<\/u>, Shewade L, <u>Yamamoto T<\/u> and Buchholz DR<\/dt>\n<dd>Unliganded thyroid hormone receptor alpha regulates developmental timing via gene repression as revealed by gene disruption in Xenopus tropicalis<\/dd>\n<dd><em><strong>Endocrinology<\/strong><\/em>,\u00a0156: 735-744, 2015 <span style=\"color: #cc0000; font-size: small;\"><b>Endocrinology\u306eNews and Views\u3001Cell &amp; Bioscience\u306eCommentary\u306b\u30d4\u30c3\u30af\u30a2\u30c3\u30d7<\/b><\/span><\/dd>\n<dt>Li HL, Fujimoto N, Sasakawa N, Shirai S, Ohkame T, <u>Sakuma T<\/u>, Tanaka M, Amano N, Watabnabe A, Sakurai H, <u>Yamamoto T<\/u>, Yamanaka S and Hotta A<\/dt>\n<dd>Precise Correction of the Dystrophin Gene in Duchenne Muscular Dystrophy Patient Induced Pluripotent Stem Cells by TALEN and CRISPR-Cas9<\/dd>\n<dd><em><strong>Stem Cell Reports<\/strong><\/em>,\u00a04: 143-154, 2015 <span style=\"color: #cc0000; font-size: small;\"><b>\u671d\u65e5\u65b0\u805e\u3001\u8aad\u58f2\u65b0\u805e\u3001\u6bce\u65e5\u65b0\u805e\u3001\u5171\u540c\u901a\u4fe1\u3088\u308a\u914d\u4fe1\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt><u>Sakuma T<\/u><\/dt>\n<dd>Front-line of genome editing technology for animal cell engineering<\/dd>\n<dd><em><strong>BMC Proceedings<\/strong><\/em>,\u00a09(Suppl 9): O1, 2015<\/dd>\n<dt>Okada J, Kikuta S, Gusev O, Suetsugu Y, Cornette R, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Kikawada T<\/dt>\n<dd>Construction of Optimized CRISPR\/Cas System to Reveal the Mechanisms of Anhydrobiosis in the Sleeping Chironomid<\/dd>\n<dd><em><strong>Cryobiology and Cryotechnology<\/strong><\/em>,\u00a061: 69-73, 2015<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>Ochiai H and <u>Yamamoto T<\/u><\/dt>\n<dd>Genome editing using zinc-finger nucleases (ZFNs) and transcription activator-like effector nucleases (TALENs)<\/dd>\n<dd><em><strong><a href=\"http:\/\/www.springer.com\/life+sciences\/animal+sciences\/book\/978-4-431-55226-0\" target=\"_blank\" rel=\"noopener\">Targeted Genome Editing Using Site-Specific Nucleases: ZFNs, TALENs, and the CRISPR\/Cas9 System<\/a><\/strong> (Ed by Yamamoto T)<\/em>,\u00a0Springer, pp3-24 (2015)<\/dd>\n<dt><u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>CRISPR\/Cas9: The Leading Edge of Genome Editing Technology<\/dd>\n<dd><em><strong><a href=\"http:\/\/www.springer.com\/life+sciences\/animal+sciences\/book\/978-4-431-55226-0\" target=\"_blank\" rel=\"noopener\">Targeted Genome Editing Using Site-Specific Nucleases: ZFNs, TALENs, and the CRISPR\/Cas9 System<\/a><\/strong> (Ed by Yamamoto T)<\/em>,\u00a0Springer, pp25-41 (2015)<\/dd>\n<dt><u>Sakamoto N<\/u><\/dt>\n<dd>Genome editing in sea urchin<\/dd>\n<dd><em><strong><a href=\"http:\/\/www.springer.com\/life+sciences\/animal+sciences\/book\/978-4-431-55226-0\" target=\"_blank\" rel=\"noopener\">Targeted Genome Editing Using Site-Specific Nucleases: ZFNs, TALENs, and the CRISPR\/Cas9 System<\/a><\/strong> (Ed by Yamamoto T)<\/em>,\u00a0Springer, pp97-106 (2015)<\/dd>\n<dt><u>Suzuki KT<\/u> and Hayashi T<\/dt>\n<dd>Genome Editing Using Site-Specific Nucleases in Amphibians<\/dd>\n<dd><em><strong><a href=\"http:\/\/www.springer.com\/life+sciences\/animal+sciences\/book\/978-4-431-55226-0\" target=\"_blank\" rel=\"noopener\">Targeted Genome Editing Using Site-Specific Nucleases: ZFNs, TALENs, and the CRISPR\/Cas9 System<\/a><\/strong> (Ed by Yamamoto T)<\/em>,\u00a0Springer, pp133-149 (2015)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u><\/dt>\n<dd><strong>\u8ad6\u6587\u3060\u3051\u3067\u306f\u308f\u304b\u3089\u306a\u3044\u3000\u30b2\u30ce\u30e0\u7de8\u96c6\u6210\u529f\u306e\u79d8\u8a23Q&amp;A<\/strong> (2015)<\/dd>\n<dt><u>\u4e2d\u51fa\u7fd4\u592a<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u30db\u30eb\u30e2\u30f3\u3068\u81e8\u5e8a<\/strong>\u3001Vol.62(2)\u3001p67-72 (2015)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>ZFN, TALEN, CRISPR\/Cas9\u30b7\u30b9\u30c6\u30e0\u3068\u306f\u3001<strong>\u9032\u5316\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853<\/strong>\u3001p11-14 (2015)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u76f8\u540c\u7d44\u63db\u3048\u306b\u4f9d\u5b58\u3057\u306a\u3044\u7c21\u4fbf\u30fb\u6b63\u78ba\u30fb\u9ad8\u52b9\u7387\u306a\u907a\u4f1d\u5b50\u30ce\u30c3\u30af\u30a4\u30f3\u6cd5\uff1aPITCh\u30b7\u30b9\u30c6\u30e0\u3001<strong>\u9032\u5316\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853<\/strong>\u3001p59-66 (2015)<\/dd>\n<dt><u>\u5742\u6839\u7950\u4eba<\/u>\u3001<u>\u5c71\u672c \u5353<\/u>\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u><\/dt>\n<dd>\u30c4\u30e1\u30ac\u30a8\u30eb\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u9032\u5316\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853<\/strong>\u3001p179-187 (2015)<\/dd>\n<dt>\u9ad8\u7530 \u671b\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u790e\u3068\u5fdc\u7528\uff1a\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3068\u7acb\u4f53\u57f9\u990a\u6280\u8853\u306e\u878d\u5408\u3092\u4f8b\u306b\u3001<strong>\u30ca\u30ce\u5b66\u4f1a\u4f1a\u5831<\/strong>\u3001Vol.13(2)\u3001p79-84 (2015)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u201call-in-one\u201dCRISPR\/Cas9\u30d9\u30af\u30bf\u30fc\u30b7\u30b9\u30c6\u30e0\u3092\u7528\u3044\u305f\u591a\u91cd\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u5b9f\u9a13\u533b\u5b66<\/strong>\u3001Vol.33(6)\u3001p959-965 (2015)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u306e\u73fe\u72b6\u3068\u5c55\u671b\u3001<strong>\u518d\u751f\u533b\u7642<\/strong>\u3001Vol.14(1)\u3001p34-40 (2015)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>Platinum TALEN\u304a\u3088\u3073CRISPR\/Cas9\u3092\u7528\u3044\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u6bd4\u8f03\u5185\u5206\u6ccc\u5b66<\/strong>\u3001Vol.41(154)\u3001p11-13 (2015)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u57fa\u790e\u3001<strong>\u533b\u5b66\u306e\u3042\u3086\u307f<\/strong>\u3001Vol.252(2)\u3001p147-151 (2015)<\/dd>\n<\/dl>\n<p><strong>\u3010\u7279\u8a31\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt>\u843d\u5408 \u535a\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd><\/dd>\n<dd>\u7d30\u80de\u306e\u4f5c\u88fd\u65b9\u6cd5\u304a\u3088\u3073\u8a72\u4f5c\u88fd\u65b9\u6cd5\u3067\u4f5c\u88fd\u3055\u308c\u305f\u7d30\u80de\u3001\u7279\u98582015-080648 (2015)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2014\"><\/a><\/p>\n<h3>2014\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>Nakade S*<\/u>, Tsubota T*, <u>Sakane Y*<\/u>, Kume S, <u>Sakamoto N<\/u>, Obara M, Daimon T, Sezutsu H, <u>Yamamoto T<\/u>, <u>Sakuma T#<\/u> and <u>Suzuki K#<\/u><\/dt>\n<dd>Microhomology-mediated end-joining-dependent integration of donor DNA in cells and animals using TALENs and CRISPR\/Cas9<\/dd>\n<dd><em><strong>Nature Communications<\/strong><\/em>,\u00a05: 5560, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u672c\u7d4c\u6e08\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u5171\u540c\u901a\u4fe1\u3088\u308a\u914d\u4fe1\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt>Ochiai H, Sugawara T, <u>Sakuma T<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Stochastic promoter activation affects Nanog expression variability in mouse embryonic stem cells<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a04: 7125, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt>Hiruta C, Ogino Y, <u>Sakuma T<\/u>, Toyota K, Miyagawa S, <u>Yamamoto T<\/u> and Iguchi T<\/dt>\n<dd>Targeted gene disruption by use of transcription activator-like effector nuclease (TALEN) in the water flea Daphnia pulex<\/dd>\n<dd><em><strong>BMC Biotechnology<\/strong><\/em>,\u00a014: 95, 2014<\/dd>\n<dt>Kaneko T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Mashimo T<\/dt>\n<dd>Simple knockout by electroporation of engineered endonucleases into intact rat embryos<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a04: 6382, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587\u3001BioTechnique\u8a8c<\/b><\/span><\/dd>\n<dt>Sawai S, Ohyama K, Yasumoto S, Seki H, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Takebayashi Y, Kojima M, Sakakibara H, Aoki T, Muranaka T, Saito K and Umemoto N.<\/dt>\n<dd>Sterol Side Chain Reductase 2 Is a Key Enzyme in the Biosynthesis of Cholesterol, the Common Precursor of Toxic Steroidal Glycoalkaloids in Potato<\/dd>\n<dd><em><strong>Plant Cell<\/strong><\/em>,\u00a026: 3763-3774, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001\u6642\u4e8b\u901a\u4fe1\u3088\u308a\u914d\u4fe1<\/b><\/span><\/dd>\n<dt>Kazuki Y, Yakura Y, Abe S, Osaki M, Kajitani N, Kazuki K, Takehara S, Honma K, Suemori H, Yamazaki S, <u>Sakuma T<\/u>, Toki T, Shimizu R, Nakauchi H, <u>Yamamoto T<\/u> and Oshimura M<\/dt>\n<dd>Down syndrome-associated haematopoiesis abnormalities created by chromosome transfer and genome editing technologies<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a04: 6136, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u672c\u6d77\u65b0\u805e<\/b><\/span><\/dd>\n<dt>Ninagawa S, Okada T, Sumitomo Y, Kamiya Y, Kato K, Horimoto S, Ishikawa T, Takeda S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Mori K<\/dt>\n<dd>EDEM2 initiates mammalian glycoprotein ERAD by catalyzing the first mannose trimming step<\/dd>\n<dd><em><strong>Journal of Cell Biology<\/strong><\/em>,\u00a0206: 347-356, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>F1000Prime Recommended\u3001\u4eac\u90fd\u65b0\u805e\u3001\u4e2d\u65e5\u65b0\u805e\u3001\u79d1\u5b66\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Nakagawa Y*, <u>Sakuma T*<\/u>, Nakagata N, Yamasaki S, Takeda N, Ohmuraya M and <u>Yamamoto T<\/u><\/dt>\n<dd>Application of oocyte cryopreservation technology in TALEN-mediated mouse genome editing<\/dd>\n<dd><em>\u00a0<strong>Experimental Animals<\/strong><\/em>,63: 349-355, 2014<\/dd>\n<dt>Yasue A, Mitsui SN, Watanabe T, <u>Sakuma T<\/u>, Oyadomari S, <u>Yamamoto T<\/u>, Noji S, Mito T and Tanaka E<\/dt>\n<dd>Highly efficient targeted mutagenesis in one-cell mouse embryos mediated by the TALEN and CRISPR\/Cas systems<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a04: 5705, 2014<\/dd>\n<dt><u>Sakuma T<\/u>, <u>Nishikawa A<\/u>, Kume S, Chayama K and <u>Yamamoto T<\/u><\/dt>\n<dd>Multiplex genome engineering in human cells using all-in-one CRISPR\/Cas9 vector system<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a04: 5400, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt>Yoshida K, Treen N, Hozumi A, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Sasakura Y<\/dt>\n<dd>Germ cell mutations of the ascidian Ciona intestinalis with TALE nucleases<\/dd>\n<dd><em><strong>Genesis<\/strong><\/em>,\u00a052: 431-439, 2014<\/dd>\n<dt><u>Tokumasu D*<\/u>, <u>Sakuma T*<\/u>, Hayashi Y, <u>Hosoi S<\/u>, Hiyama E and <u>Yamamoto T<\/u><\/dt>\n<dd>FAST-id system for enrichment of cells with TALEN-induced mutations and large deletions<\/dd>\n<dd><em><strong>Genes to Cells<\/strong><\/em>,\u00a019: 419-431, 2014<\/dd>\n<dt>Ochiai H*, Miyamoto T*, Kanai A, Hosoba K, <u>Sakuma T<\/u>, Kudo Y, Asami K, Ogawa A, Watanabe A, Kajii T, <u>Yamamoto T<\/u> and Matsuura S<\/dt>\n<dd>TALEN-mediated single-base-pair editing identification of an intergenic mutation upstream of BUB1B as causative of PCS (MVA) syndrome<\/dd>\n<dd><em><strong>Proc Natl Acad Sci U S A<\/strong><\/em>,\u00a0111: 1461-1466, 2014 <span style=\"color: #cc0000; font-size: small;\"><b>PNAS Commentary\u306b\u30d4\u30c3\u30af\u30a2\u30c3\u30d7<\/b><\/span><\/dd>\n<dt>Treen N, Yoshida K, <u>Sakuma T<\/u>, Sasaki H, Kawai N, <u>Yamamoto T<\/u> and Sasakura Y<\/dt>\n<dd>Tissue-specific and ubiquitous gene knockouts in Ciona by electroporating TALENs provide new approaches to investigate gene functions<\/dd>\n<dd><em><strong>Development<\/strong><\/em>,\u00a0141: 481-487, 2014<\/dd>\n<dt>Sugi T*, <u>Sakuma T*<\/u>, Ohtani T and <u>Yamamoto T<\/u><\/dt>\n<dd>Versatile strategy for isolating TALEN-mediated knockout mutants in Caenorhabditis elegans.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 78-85, 2014<\/dd>\n<dt><u>Sakane Y<\/u>, <u>Sakuma T<\/u>, Kashiwagi K\uff0cKashiwagi A, <u>Yamamoto T<\/u> and <u>Suzuki K<\/u><\/dt>\n<dd>Targeted mutagenesis of multiple and paralogous genes in Xenopus laevis using two pairs of TALENs.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 108-114, 2014<\/dd>\n<dt><u>Hosoi S<\/u>, <u>Sakuma T<\/u>, <u>Sakamoto N<\/u> and <u>Yamamoto T<\/u><\/dt>\n<dd>Targeted mutagenesis in sea urchin embryos using TALENs.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 92-97, 2014<\/dd>\n<dt>Hayashi T, Sakamoto K, <u>Sakuma T<\/u>, Yokotani N, Inoue T, Kawaguchi E, Agata K, <u>Yamamoto T<\/u> and Takeuchi T<\/dt>\n<dd>TALENs efficiently disrupt the target gene in Iberian ribbed newts (Pleurodeles waltl), an experimental model animal for regeneration.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 115-121, 2014<\/dd>\n<dt>Kondo T, <u>Sakuma T<\/u>, Wada H, Akimoto A, <u>Yamamoto T<\/u> and Hayashi S<\/dt>\n<dd>TALEN-induced gene knock out in Drosophila.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 86-91, 2014<\/dd>\n<dt>Nakagawa Y, <u>Yamamoto T<\/u>, <u>Suzuki KI<\/u>, Araki K, Takeda N, Ohmuraya M and <u>Sakuma T<\/u><\/dt>\n<dd>Screening methods to identify TALEN-mediated knockout mice.<\/dd>\n<dd><em><strong>Exp Anim<\/strong><\/em>,\u00a063: 79-84, 2014<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>Yamamoto T<\/u> and Nakamura H<\/dt>\n<dd>Targeted genome editing.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 1, 2014<\/dd>\n<dt><u>Sakuma T<\/u> and Woltjen K<\/dt>\n<dd>Nuclease-mediated genome editing: At the front-line of functional genomics technology.<\/dd>\n<dd><em><strong>Dev Growth Differ<\/strong><\/em>,\u00a056: 2-13, 2014<\/dd>\n<dt>Hanada H, Kashiwagi K, <u>Suzuki K<\/u>, Tazawa I, <u>Yamamoto T<\/u> and Kashiwagi A<\/dt>\n<dd>Suppression of anuran metamorphosis by synthetic chemical compounds<\/dd>\n<dd><em><strong>Frogs: Genetic Diversity, Neural Development and Environmental Influences<\/strong> (Ed by Lambert H),<\/em>\u00a073-88, 2014<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u7dcf\u8aac\u3001<strong>\u30b2\u30ce\u30e0\u7de8\u96c6\u30cf\u30f3\u30c9\u30d6\u30c3\u30af\uff08\u30b3\u30b9\u30e2\u30d0\u30a4\u30aa\uff09<\/strong>\u3001p2-3 (2014)<\/dd>\n<dt><u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u90e8\u4f4d\u7279\u7570\u7684\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u5229\u7528\u3057\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3001<strong>\u6574\u5f62\u30fb\u707d\u5bb3\u5916\u79d1<\/strong>\u3001Vol.57\u3001p1609-1614 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u9ad8\u6d3b\u6027\u578bPlatinum TALEN\u304a\u3088\u3073CRISPR\/Cas9\u3092\u7528\u3044\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>DNA\u9451\u5b9a<\/strong>\u3001Vol.6 (2014)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\uff0c<u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u90e8\u4f4d\u7279\u7570\u7684\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u5229\u7528\u3057\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u6708\u520a\u30d0\u30a4\u30aa\u30a4\u30f3\u30c0\u30b9\u30c8\u30ea\u30fc<\/strong>, 2014\u5e7411\u6708\u53f7 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306b\u3088\u308b\u907a\u4f1d\u5b50\u6539\u5909\u6280\u8853\u3001<strong>THE LUNG perspectives<\/strong>\u3001Vol.22(4)\u3001p71-75 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u52d5\u7269\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u306e\u6700\u524d\u7dda\u3001<strong>\u4e5d\u5dde\u5b9f\u9a13\u52d5\u7269\u96d1\u8a8c<\/strong>\u3001Vol.30\u3001p19-23 (2014)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\uff0c<u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u90e8\u4f4d\u7279\u7570\u7684\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u57fa\u76e4\u3068\u3059\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3001<strong>\u30a6\u30a4\u30eb\u30b9<\/strong>\u3001Vol.64(1)\u300175-82 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u30c4\u30fc\u30eb\u306e\u958b\u767a\u306e\u6b74\u53f2\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p8-13 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u306e\u539f\u7406\u3068\u5fdc\u7528\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p14-20 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>TALEN\u3084CRISPR\/Cas9\u3092\u81ea\u4f5c\u3059\u308b\u306b\u306f\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p23-28 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>TALEN\u3084CRISPR\/Cas9\u306e\u6d3b\u6027\u8a55\u4fa1\u6cd5\u3068\u5909\u7570\u306e\u691c\u51fa\u6cd5\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p29-35 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>TALEN\u3084CRISPR\/Cas9\u306b\u3088\u308b\u30bf\u30fc\u30b2\u30c6\u30a3\u30f3\u30b0\u6226\u7565\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p36-41 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u30c4\u30fc\u30eb\u306e\u4f5c\u88fd\u6cd5\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p46-61 (2014)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>CRISPR\/Cas9\u30c0\u30d6\u30eb\u30cb\u30c3\u30ab\u30fc\u30bc\u3092\u7528\u3044\u305f\u907a\u4f1d\u5b50\u6539\u5909\u6cd5\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p120-121 (2014)<\/dd>\n<dt>\u6797 \u5229\u61b2\u3001<u>\u5742\u6839\u4f51\u4eba<\/u>\u3001\u7af9\u5185 \u9686\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u30c4\u30fc\u30eb\u306e\u4f5c\u88fd\u6cd5\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300c\u4eca\u3059\u3050\u59cb\u3081\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u300d<\/strong>\u3001p180-188 (2014)<\/dd>\n<dt><u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353&lt;<\/u>\/dt&gt;<\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3092\u7528\u3044\u305f\u500b\u4f53\u30ec\u30d9\u30eb\u306e\u6a5f\u80fd\u89e3\u6790\uff1a\u30c4\u30e1\u30ac\u30a8\u30eb\u3092\u4f8b\u306b\u3001<strong>\u6bd4\u8f03\u5185\u5206\u6ccc\u5b66<\/strong>\u3001Vol.40\u3001p35-36 (2014)<\/dd>\n<dt>\u674e \u7d05\u6885\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001\u5800\u7530\u79cb\u6d25\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>TALEN\u306b\u3088\u308b\u907a\u4f1d\u5b50\u30bf\u30fc\u30b2\u30c6\u30a3\u30f3\u30b0\u3001<strong>\u5b9f\u9a13\u533b\u5b66\u5225\u518a\u300cES\u30fbiPS\u7d30\u80de\u5b9f\u9a13\u30b9\u30bf\u30f3\u30c0\u30fc\u30c9\u300d<\/strong>\u3001p324-336 (2014)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u90e8\u4f4d\u7279\u7570\u7684\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u306b\u3088\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u3068\u52d5\u7269\u306b\u304a\u3051\u308b\u5229\u7528\u3001<strong>\u751f\u7269\u306e\u79d1\u5b66\u300c\u907a\u4f1d\u300d<\/strong>\u3001Vol.68(2)\u3001p130-134 (2014)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u4eba\u5de5\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u7528\u3044\u305f\u57f9\u990a\u7d30\u80de\u3084\u52d5\u7269\u3067\u306e\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u7d30\u80de<\/strong>\u3001Vol.46(2)\u3001p92-95 (2014)<\/dd>\n<dt><u>\u5742\u672c \u5c1a\u662d<\/u>, \u7c9f\u6d25 \u6681\u7d00<\/dt>\n<dd>\u30a4\u30f3\u30b9\u30ec\u30fc\u30bf\u30fc\u3068\u30af\u30ed\u30de\u30c1\u30f3\u69cb\u9020, <strong>\u751f\u4f53\u306e\u79d1\u5b66\u30fb\u7279\u96c6\u300c\u751f\u547d\u52d5\u614b\u30b7\u30b9\u30c6\u30e0\u79d1\u5b66\u300d<\/strong>,65, 412-413 (2014)<\/dd>\n<\/dl>\n<p><strong>\u3010\u7279\u8a31\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u5742\u6839\u7950\u4eba<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd><\/dd>\n<dd>\u6838\u9178\u633f\u5165\u7528\u30d9\u30af\u30bf\u30fc\u3001PCT\/JP2014\/079515 (2014)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2013\"><\/a><\/p>\n<h3>2013\u5e74<\/h3>\n<p><strong>\u3010\u539f\u8457\u8ad6\u6587\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>Sakuma T<\/u>, Ochiai H, Kaneko T, Mashimo T, <u>Tokumasu D<\/u>, <u>Sakane Y<\/u>, <u>Suzuki K<\/u>, Miyamoto T, <u>Sakamoto N<\/u>, Matsuura S and <u>Yamamoto T<\/u><\/dt>\n<dd>Repeating pattern of non-RVD variations in DNA-binding modules enhances TALEN activity.<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a03: 3379, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Kato T, Miyata K, Sonobe M, Yamashita S, Tamano M, Miura K, Kanai Y, Miyamoto S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Inui M, Kikusui T, Asahara H, Takada S<\/dt>\n<dd>Production of Sry knockout mouse using TALEN via oocyte injection.<\/dd>\n<dd><em><strong>Scientific Reports<\/strong><\/em>,\u00a03: 3136, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587\u3001BioTechnique\u8a8c<\/b><\/span><\/dd>\n<dt><u>Sakuma T<\/u>, Hosoi S, Woltjen K, <u>Suzuki KI<\/u>, Kashiwagi K, Wada H, Ochiai H, Miyamoto T, Kawai N, Sasakura Y, Matsuura S, Okada Y, Kawahara A, Hayashi S and <u>Yamamoto T<\/u><\/dt>\n<dd>Efficient TALEN construction and evaluation methods for human cell and animal applications.<\/dd>\n<dd><em><strong>Genes Cells<\/strong><\/em>,\u00a018: 315-326, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>Genes to Cells\u306e2013\u5e74\u306eMost Accesed\u3068Most cited\u306eArticle<\/b><\/span><\/dd>\n<dt>Mashimo T, Kaneko T, <u>Sakuma T<\/u>, Kobayashi J, Kunihiro Y, Voigt B, <u>Yamamoto T<\/u> and Serikawa T<\/dt>\n<dd>Efficient gene targeting by TAL effector nucleases coinjected with exonucleases in zygotes.<\/dd>\n<dd><em><strong>Scientific Report<\/strong>s<\/em>,\u00a03, 1253, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>\u4e2d\u56fd\u65b0\u805e\u3001\u4eac\u90fd\u65b0\u805e\u3001\u65e5\u520a\u5de5\u696d\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt><u>Mitsunaga-Nakatsubo K<\/u>, Akimoto Y, Kusunoki S and Kawakami H.<\/dt>\n<dd>Novel structure of hepatic extracellular matrices containing arylsulfatase A.<\/dd>\n<dd><em><strong>Okajimas Folia Anat Jpn<\/strong><\/em>,\u00a090: 17-22, 2013<\/dd>\n<dt><u>Suzuki KI<\/u>, <u>Isoyama Y<\/u>, Kashiwagi K, <u>Sakuma T<\/u>, Ochiai H, <u>Sakamoto N<\/u>, Furuno N, Kashiwagi A and <u>Yamamoto T<\/u><\/dt>\n<dd>High efficiency TALENs enable F0 functional analysis by targeted gene disruption in Xenopus laevis embryos.<\/dd>\n<dd><em><strong>Biology Open<\/strong><\/em>,\u00a02: 448-452, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>BiO&#8217;s top five most-read articles for 2013<\/b><\/span><\/dd>\n<dt>Hisano Y, Ota S, Arakawa S, Muraki M, Kono N, Oshita K, <u>Sakuma T<\/u>, Tomita M, <u>Yamamoto T<\/u>, Okada Y and Kawahara A<\/dt>\n<dd>Quantitative assay for TALEN activity at endogenous genomic loci.<\/dd>\n<dd><em><strong>Biology Open<\/strong><\/em>,\u00a02: 363-367, 2013 <span style=\"color: #cc0000; font-size: small;\"><b>BiO&#8217;s top five most-read articles for 2013<\/b><\/span><\/dd>\n<dt>Oulhen N, Yoshida T, Yajima M, Song J, <u>Sakuma T<\/u>, <u>Sakamoto N<\/u>, <u>Yamamoto T<\/u> and Wessel GM<\/dt>\n<dd>The 3\u2019UTR of Nanos2 directs enrichment in the germ cell lineage of the sea urchin.<\/dd>\n<dd><em><strong>Dev Biol<\/strong><\/em>,\u00a0377: 275-283, 2013<\/dd>\n<dt>Ansai S, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u>, Ariga H, Uemura N, Takahashi R and Kinoshita M.<\/dt>\n<dd>Efficient targeted mutagenesis in medaka using custom-designed transcription activator-like effector nucleases (TALENs).<\/dd>\n<dd><em><strong>Genetics<\/strong><\/em>, 193: 739-749, 2013<\/dd>\n<dt>Hozumi A, Yoshida R, Horie T, <u>Sakuma T<\/u>, <u>Yamamoto T<\/u> and Sasakura Y<\/dt>\n<dd>Enhancer activity sensitive to the orientation of the gene it regulates in the chordate genome.<\/dd>\n<dd><em><strong>Dev Biol<\/strong><\/em>,\u00a037: 79-91, 2013<\/dd>\n<\/dl>\n<p><strong>\u3010\u7dcf\u8aac\u30fb\u8457\u66f8\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u3092\u5229\u7528\u3057\u305f\u57f9\u990a\u7d30\u80de\u3084\u52d5\u7269\u306b\u304a\u3051\u308b\u6a19\u7684\u907a\u4f1d\u5b50\u306e\u6539\u5909\u3001<strong>\u8840\u7ba1<\/strong>\u3001Vol.36\u3001p123-128 (2013)<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u9ad8\u6d3b\u6027\u578bTALEN\u306e\u958b\u767a\u3068\u69d8\u3005\u306a\u52d5\u7269\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u95a2\u897f\u5b9f\u9a13\u52d5\u7269\u7814\u7a76\u4f1a\u4f1a\u5831<\/strong>\u3001Vol.35\u3001p75-78 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u4eba\u5de5\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u7528\u3044\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u7814\u7a76\u306e\u6b74\u53f2\u3068\u73fe\u72b6\u3001<strong>DNA\u9451\u5b9a<\/strong>\u3001Vol.5\u3001p1-8 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3092\u7528\u3044\u305f\u907a\u4f1d\u5b50\u6539\u5909\u304a\u3088\u3073\u67d3\u8272\u4f53\u6539\u5909\u52d5\u7269\u306b\u3064\u3044\u3066\u3001<strong>LABIO21<\/strong>\u3001Vol.54\u3001p16-18 (2013)<\/dd>\n<dt><u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u68d8\u76ae\u52d5\u7269\u306e\u30a6\u30cb\u3001<strong>\u751f\u7269\u5de5\u5b66\u4f1a\u8a8c<\/strong>\u3001Vol.91(8)\u3001p473-476 (2013)<\/dd>\n<dt><u>\u5c71\u672c\u3000\u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u52d5\u7269\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u306e\u73fe\u72b6\u3068\u53ef\u80fd\u6027\u3001<strong>\u30d0\u30a4\u30aa\u30b5\u30a4\u30a8\u30f3\u30b9\u3068\u30a4\u30f3\u30c0\u30b9\u30c8\u30ea\u30fc<\/strong>\u3001Vol.71(4)\u3001p365-368 (2013)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u9769\u547d\u300c\u57fa\u790e\u306e\u57fa\u790e\u300d\u3001<strong>\u7d30\u80de\u5de5\u5b66<\/strong>\u3001Vol.32(5)\u3001p506-509 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>TALEN\u306e\u52b9\u7387\u7684\u306a\u4f5c\u88fd\u3068\u52d5\u7269\u500b\u4f53\u3078\u306e\u5fdc\u7528\u3001<strong>\u7d30\u80de\u5de5\u5b66<\/strong>\u3001Vol.32(5)\u3001p510-514 (2013)<\/dd>\n<dt>\u843d\u5408\u3000\u535a\u3001\u67f4\u7530\u9054\u592b\u3001<u>\u5c71\u672c\u3000\u5353<\/u><\/dt>\n<dd>\u30b2\u30ce\u30e0\u7de8\u96c6\u6280\u8853\u3092\u7528\u3044\u305f\u907a\u4f1d\u5b50\u767a\u73fe\u306e\u5b9a\u91cf\u7684\u30a4\u30e1\u30fc\u30b8\u30f3\u30b0\u3001<strong>\u7d30\u80de\u5de5\u5b66<\/strong>\u3001Vol.32(5)\u3001p538-542 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u><\/dt>\n<dd>RNA\u8a98\u5c0e\u578b\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\uff1aCRISPR\/Cas\u30b7\u30b9\u30c6\u30e0\u306b\u3088\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u7d30\u80de\u5de5\u5b66<\/strong>\u3001Vol.32(5)\u3001p515-517 (2013)<\/dd>\n<dt><u>\u5c71\u672c \u5353<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u><\/dt>\n<dd>\u6a19\u7684\u907a\u4f1d\u5b50\u306e\u6539\u5909\u3092\u53ef\u80fd\u306b\u3059\u308b\u4eba\u5de5\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u306e\u958b\u767a\u3001<strong>\u5316\u5b66\u5de5\u696d<\/strong>\u3001Vol.64(4)\u3001p260-264 (2013)<\/dd>\n<dt>\u843d\u5408 \u535a\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001\u677e\u6d66\u4f38\u4e5f\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>TALE nuclease (TALEN)\u3092\u7528\u3044\u305f\u57f9\u990a\u7d30\u80de\u306b\u304a\u3051\u308b\u30b2\u30ce\u30e0\u7de8\u96c6\u3001<strong>\u5b9f\u9a13\u533b\u5b66<\/strong>\u3001Vol.31(1)\u3001p95-100 (2013)<\/dd>\n<\/dl>\n<p><strong>\u3010\u7279\u8a31\u3011<\/strong><\/p>\n<dl class=\"work list_first\">\n<dt><u>\u9234\u6728\u8ce2\u4e00<\/u>\u3001<u>\u5742\u6839\u7950\u4eba<\/u>\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u6838\u9178\u633f\u5165\u7528\u30d9\u30af\u30bf\u30fc\u3001\u7279\u98582013-230349 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001\u843d\u5408 \u535a\u3001\u677e\u6d66\u4f38\u4e5f\u3001\u5bae\u672c\u9054\u96c4\u3001<u>\u5c71\u672c\u5353<\/u><\/dt>\n<dd>\uff24\uff2e\uff21\u7d50\u5408\u30c9\u30e1\u30a4\u30f3\u3092\u542b\u3080\u30dd\u30ea\u30da\u30d7\u30c1\u30c9\u3001\u7279\u98582013-166768 (2013)<\/dd>\n<dt><u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5fb3\u5897\u5927\u8f14<\/u>\u3001<u>\u5742\u672c\u5c1a\u662d<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u767a\u73fe\u3055\u305b\u308b\u305f\u3081\u306e\u30d9\u30af\u30bf\u30fc\u304a\u3088\u3073\u30d9\u30af\u30bf\u30fc\u30bb\u30c3\u30c8\u3001\u306a\u3089\u3073\u306b\u5909\u7570\u5c0e\u5165\u3092\u53d7\u3051\u305f\u7d30\u80de\u306e\u53d6\u5f97\u65b9\u6cd5\u3001\u7279\u98582013-098724 (2013)<\/dd>\n<dt>\u4e2d\u6751\u5d07\u88d5\u3001\u516b\u6728\u7950\u4ecb\u3001\u5927\u5ddd\u606d\u884c\u3001<u>\u4f50\u4e45\u9593\u54f2\u53f2<\/u>\u3001<u>\u5c71\u672c \u5353<\/u><\/dt>\n<dd>PPR\u30e2\u30c1\u30fc\u30d5\u3092\u5229\u7528\u3057\u305fDNA\u7d50\u5408\u6027\u86cb\u767d\u8cea\u306e\u8a2d\u8a08\u65b9\u6cd5\u53ca\u3073\u305d\u306e\u5229\u7528\u3001\u7279\u98582013-88940 (2013)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2012\"><\/a><\/p>\n<h3>2012\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Watanabe T, Ochiai H, Sakuma T, Horch H, Hamaguchi N, Nakamura T, Bando T, Ohuchi H, Yamamoto T, Noji S and Mito T<\/dt>\n<dd>Non-transgenic genome modifications in a hemimetabolous insect using zinc-finger and TAL effector nucleases.<\/dd>\n<dd><em>Nat Commun<\/em>, <strong>3<\/strong>: 1017, 2012 <span style=\"color: #cc0000; font-size: small;\"><b>\u671d\u65e5\u65b0\u805e\u3001\u8aad\u58f2\u65b0\u805e\u3001\u4e2d\u56fd\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline\u3001Nature Japan\u6ce8\u76ee\u306e\u8ad6\u6587<\/b><\/span><\/dd>\n<dt>Ochiai H, Sakamoto N, Fujita K, Nishikawa M, Suzuki KI, Matsuura S, Miyamoto T, Sakuma T, Shibata T and Yamamoto T<\/dt>\n<dd>Zinc-finger nuclease-mediated targeted insertion of reporter genes for quantitative imaging of gene expression in sea urchin embryos.<\/dd>\n<dd><em>Proc Natl Acad Sci U S A<\/em>, <strong>109<\/strong>: 10915-10920, 2012 <span style=\"color: #cc0000; font-size: small;\"><b>\u4e2d\u56fd\u65b0\u805e\u3001\u65e5\u7d4c\u30d0\u30a4\u30aa\u30c6\u30afonline<\/b><\/span><\/dd>\n<dt>Song X, Sato Y, Felemban A, Ito A, Hossain M, Ochiai H, Yamamoto T, Sekiguchi K, Tanaka H and Ohta K<\/dt>\n<dd>Equarin is involved as an FGF signaling modulator in chick lens differentiation.<\/dd>\n<dd><em>Dev Biol<\/em>, <strong>368<\/strong>: 109-117, 2012<\/dd>\n<dt>Ansai S, Ochiai H, Kanie Y, Kamei Y, Goh Y, Kitano T, Yamamoto T and Kinoshita M<\/dt>\n<dd>Targeted disruption of exogenous EGFP gene in medaka using zinc-finger nucleases.<\/dd>\n<dd><em>Dev Growth Differ<\/em>, <strong>54<\/strong>: 546-556, 2012<\/dd>\n<dt>Kawai N, Ochiai H, Sakuma T, Yamada L, Sawada H, Yamamoto T and Sasakura Y<\/dt>\n<dd>Efficient targeted mutagenesis of the chordate Ciona intestinalis genome with zinc-finger nucleases.<\/dd>\n<dd><em>Dev Growth Differ<\/em>, <strong>54<\/strong>: 535-545, 2012 <span style=\"color: #cc0000; font-size: small;\"><b>Faculty of 1000 Recommended<\/b><\/span><\/dd>\n<dt>Takagi H, Inai Y, Watanabe S, Tatemoto S, Yajima M, Akasaka K, Yamamoto T and Sakamoto N<\/dt>\n<dd>Nucleosome exclusion from the interspecies conserved central AT-rich region of the Ars insulator.<\/dd>\n<dd><em>J Biochem<\/em>, <strong>151<\/strong>: 75-87, 2012 <span style=\"color: #cc0000; font-size: small;\"><b>JB\u8ad6\u6587\u8cde<\/b><\/span><\/dd>\n<dt>\u4f50\u4e45\u9593\u54f2\u53f2\u3001\u5742\u672c\u5c1a\u662d\u3001\u5c71\u672c \u5353<\/dt>\n<dd>\u4eba\u5de5\u30cc\u30af\u30ec\u30a2\u30fc\u30bc\u3092\u7528\u3044\u305f\u30b2\u30ce\u30e0\u7de8\u96c6\u3001Medical Science Digest\u3001Vol38(8), p328-329 (2012)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2011\"><\/a><\/p>\n<h3>2011\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Sakuma T, Ohnishi K, Fujita K, Ochiai H, Sakamoto N and Yamamoto T<\/dt>\n<dd>HpSumf1 is involved in the activation of sulfatases responsible for regulation of skeletogenesis during sea urchin development.<\/dd>\n<dd><em>Dev Genes Evol<\/em>,\u00a0<strong>221<\/strong>: 157-166, 2011<\/dd>\n<dt>\u5c71\u672c \u5353\u3001\u5742\u672c\u5c1a\u662d\u3001\u4f50\u4e45\u9593\u54f2\u53f2\u3001\u91ce\u5730\u6f84\u6674<\/dt>\n<dd>\u65b0\u898fDNA\u7d50\u5408\u30c9\u30e1\u30a4\u30f3\u304a\u3088\u3073\u305d\u308c\u3092\u542b\u3080\u65b0\u898fDNA\u5207\u65ad\u9175\u7d20\u3001\u7279\u98582011-242250 (2011)<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2010\"><\/a><\/p>\n<h3>2010\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Ochiai H, Fujita K, Suzuki K, Nishikawa M, Shibata T, Sakamoto N and Yamamoto T<\/dt>\n<dd>Targeted mutagenesis in the sea urchin embryo using zinc-finger nucleases.<\/dd>\n<dd><em>Genes Cells<\/em>,\u00a0<strong>15<\/strong>: 875-885, 2010<\/dd>\n<dt>Okamitsu Y, Yamamoto T, Fujii T, Ochiai H and Sakamoto N<\/dt>\n<dd>Dicer is required for the normal development of sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>27<\/strong>: 477-486, 2010<\/dd>\n<dt>Yajima M, Umeda R, Fuchikami T, Kataoka M, Sakamoto N, Yamamoto T and Akasaka K<\/dt>\n<dd>Implication of HpEts in gene regulatory networks responsible for specification of sea urchin skeletogenic primary mesenchyme cells<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>27<\/strong>: 638-646, 2010<\/dd>\n<dt>Fujita K, Takechi E, Sakamoto N, Sumiyoshi N, Izumi S, Miyamoto T, Matsuura S, Tsurugaya T, Akasaka K and Yamamoto T<\/dt>\n<dd>HpSulf, a heparan sulfate 6-O-endosulfatase, is involved in the regulation of VEGF signaling during sea urchin development.<\/dd>\n<dd><em>Mech Dev<\/em>,\u00a0<strong>127<\/strong>: 235-245, 2010<\/dd>\n<dt>Fujita K, Teramura N, Hattori S, Irie S, Mitsunaga-Nakatsubo K, Akimoto T, Sakamoto N, Yamamoto T and Akasaka K<\/dt>\n<dd>Mammalian arlysulfatase A functions as a novel component of the extracellular matrix.<\/dd>\n<dd><em>Connect Tissue Res<\/em>,\u00a0<strong>51<\/strong>: 388-396, 2010<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2009\"><\/a><\/p>\n<h3>2009\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Karasawa K, Sakamoto N, Fujita K, Ochiai H, Fujii T, Akasaka K and Yamamoto T<\/dt>\n<dd>Suppressor of Hairless (Su(H)) is required for foregut development in the sea urchin embryo.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>26<\/strong>: 686-690, 2009<\/dd>\n<dt>Fujii T, Sakamoto N, Ochiai H, Fujita K, Okamitsu Y, Sumiyoshi N, Minokawa T and Yamamoto T<\/dt>\n<dd>Role of the nanos homolog during sea urchin development.<\/dd>\n<dd><em>Dev Dyn<\/em>,\u00a0<strong>238<\/strong>: 2511-2521, 2009<\/dd>\n<dt>Mitsunaga-Nakatsubo K, Kusunoki S, Kawakami H, Akasaka K and Akimoto Y<\/dt>\n<dd>Cell-surface arylsulfatase A and B on sinusoidal endothelial cells, hepatocytes, and Kupffer cells in mammalian livers.<\/dd>\n<dd><em>Med Mol Morphol<\/em>,\u00a0<strong>42<\/strong>: 63-69, 2009<\/dd>\n<dt>Mitsunaga-Nakatsubo K, Akimoto Y, Kawakami H and Akasaka K<\/dt>\n<dd>Sea urchin arylsulfatase, an extracellular matrix component, is involved in gastrulation during embryogenesis.<\/dd>\n<dd><em>Dev Genes Evol<\/em>,\u00a0<strong>219<\/strong>: 281-288, 2009<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2008\"><\/a><\/p>\n<h3>2008\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Ochiai H, Sakamoto N, Suzuki K, Akasaka K and Yamamoto T<\/dt>\n<dd>The Ars insulator facilitates I-SceI meganuclease-mediated transgenesis in the sea urchin embryo.<\/dd>\n<dd><em>Dev Dyn<\/em>,\u00a0<strong>237<\/strong>: 2475-2482, 2008<\/dd>\n<dt>Hanai K, Furuhashi H, Yamamoto T, Akasaka K and Hirose S<\/dt>\n<dd>RSF Governs Silent Chromatin Formation via Histone H2Av Replacement.<\/dd>\n<dd><em>PLoS genet<\/em>,\u00a0<strong>4<\/strong>: e1000011, 2008<\/dd>\n<dt>Ochiai H, Sakamoto N, Momiyama A, Akasaka K and Yamamoto T<\/dt>\n<dd>Analysis of cis-regulatory elements controlling spatio-temporal expression of T-brain gene in sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Mech Dev<\/em>,\u00a0<strong>125<\/strong>: 2-17, 2008<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2007\"><\/a><\/p>\n<h3>2007\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Yamamoto T, Kawamoto R, Fujii T, Sakamoto N and Shibata T<\/dt>\n<dd>DNA variations within the sea urchin Otx gene enhancer.<\/dd>\n<dd><em>FEBS Lett<\/em>,\u00a0<strong>581<\/strong>: 5234-5240, 2007<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2006\"><\/a><\/p>\n<h3>2006\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Sakamoto N, Yamamoto T and Akasaka K<\/dt>\n<dd>Involvement of nuclear matrix and chromatin loop formation in the function of insulators.<\/dd>\n<dd>Chapter14 of review book,\u00a0<em>DNA Structure, Chromatin and Gene Expression<\/em>, 193-205, 2006<\/dd>\n<dt>Watanabe S, Watanabe S, Sakamoto N, Sato M and Akasaka K<\/dt>\n<dd>Functional analysis of the sea urchin-derived arylsulfatase (Ars)-element in mammalian cells.<\/dd>\n<dd><em>Genes Cells<\/em>,\u00a0<strong>11<\/strong>: 1009-1021, 2006<\/dd>\n<dt>Fujii T, Mitsunaga-Nakatsubo K, Saito I, Iida H, Sakamoto N, Akasaka K and Yamamoto T<\/dt>\n<dd>Developmental expression of HpNanos, the Hemicentrotus pulcherrimus homologue of nanos.<\/dd>\n<dd><em>Gene Expr Patterns<\/em>,\u00a0<strong>6<\/strong>: 572-577, 2006<\/dd>\n<dt>Tagashira H, Shimotori T, Sakamoto N, Katahira M, Miyanoiri Y, Yamamoto T, Mitsunaga-Nakatsubo K, Shimada H, Kusunoki S and Akasaka K<\/dt>\n<dd>Unichrom, a novel nuclear matrix protein, binds to the Ars insulator and canonical MARs.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>23<\/strong>: 9-21, 2006<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2005\"><\/a><\/p>\n<h3>2005\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Ohtsuki, T., Otsuki, M., Murakami, Y., Maekawa, T., Yamamoto, T., Akasaka, K., Takeuchi, S. and Takahashi S<\/dt>\n<dd>Organ-specific and age-dependent expression of insulin-like growth factor-I (IGF-I) mRNA variants: IGF-IA and IB mRNAs in the mouse.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>22<\/strong>: 1011-1021, 2005<\/dd>\n<dt>Yamazaki A, Kawabata R, Shiomi K, Amemiya S, Sawaguchi M, Mitsunaga-Nakatsubo K and Yamaguchi M<\/dt>\n<dd>The micro1 gene is necessary and sufficient for micromere differentiation and mid\/hindgut-inducing activity in the sea urchin embryo.<\/dd>\n<dd><em>Dev Genes Evol<\/em>,\u00a0<strong>215<\/strong>: 450-459, 2005<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2004\"><\/a><\/p>\n<h3>2004\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Moritani K, Tagashira H, Shimotori T, Sakamoto N, Tanaka S, Takata K, Mitsunaga-Nakatsubo K, Bojiiwa Y, Yamamoto T, Shimada H and Akasaka K<\/dt>\n<dd>A new G-stretch-DNA-binding protein, Unichrom, displays cell-cycle-dependent expression in sea urchin embryos.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>46<\/strong>: 335-341, 2004<\/dd>\n<dt>Hayashibara Y, Mitsunaga-Nakatsubo K, Sakamoto N, Shimotori T, Akasaka K and Yamamoto T<\/dt>\n<dd>The Otx binding site is required for the activation of HpOtxL mRNA expression in the sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>46<\/strong>: 61-67, 2004<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2003\"><\/a><\/p>\n<h3>2003\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Kurita M, Kondoh H, Mitsunaga-Nakatsubo K, Shimotori T, Sakamoto N, Yamamoto T, Shimada H, Takata K and Akasaka K<\/dt>\n<dd>Utilization of a particle gun DNA introduction system for the analysis of cis-regulatory elements controlling the spatial expression pattern of the arylsulfatase gene ( HpArs) in sea urchin embryos.<\/dd>\n<dd><em>Dev Genes Evol<\/em>,\u00a0<strong>213<\/strong>: 44-49, 2003<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2002\"><\/a><\/p>\n<h3>2002\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Fuchikami T, Mitsunaga-Nakatsubo K, Amemiya S, Hosomi T, Watanabe T, Kurokawa D, Kataoka M, Harada Y, Satoh N, Kusunoki S, Takata K, Shimotori T, Yamamoto T, Sakamoto N, Shimada H and Akasaka K<\/dt>\n<dd>T-brain homologue (HpTb) is involved in the archenteron induction signals of micromere descendant cells in the sea urchin embryo.<\/dd>\n<dd><em>Development<\/em>,\u00a0<strong>129<\/strong>: 5205-5216, 2002<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"2000\"><\/a><\/p>\n<h3>2000\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Kiyama T, Sasai K, Takata K, Mitsunaga-Nakatsubo K, Shimada H and Akasaka K<\/dt>\n<dd>CAAT sites are required for the activation of the H. pulcherrimus Ars gene by Otx.<\/dd>\n<dd><em>Dev Genes Evol<\/em>,\u00a0<strong>210<\/strong>: 583-590, 2000<\/dd>\n<dt>Ogawa M, Akasaka K, Mitsunaga-Nakatsubo K and Shimada H<\/dt>\n<dd>Sox regulates transcription of the sea urchin arylsulfatase gene.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>42<\/strong>: 429-435, 2000<\/dd>\n<dt>Mitsunaga-Nakatsubo K, Kawasaki T, Takeda K, Akasaka K and Shimada H<\/dt>\n<dd>Lim1-related homeobox gene (HpLim1) expressed in sea urchin embryo.<\/dd>\n<dd><em>Zygote<\/em>,\u00a0<strong>8 Suppl 1<\/strong>: S71-72, 2000<\/dd>\n<dt>Kurokawa D, Kitajima T, Mitsunaga-Nakatsubo K, Amemiya S, Shimada H and Akasaka K<\/dt>\n<dd>HpEts implicated in primary mesenchyme cell differentiation of the sea urchin (Hemicentrotus pulcherrimus) embryo.<\/dd>\n<dd><em>Zygote<\/em>,\u00a0<strong>8 Suppl 1<\/strong>: S33-34, 2000<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"1999\"><\/a><\/p>\n<h3>1999\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Kurokawa D, Kitajima T, Mitsunaga-Nakatsubo K, Amemiya S, Shimada H and Akasaka K<\/dt>\n<dd>HpEts, an ets-related transcription factor implicated in primary mesenchyme cell differentiation in the sea urchin embryo.<\/dd>\n<dd><em>Mech Dev<\/em>,\u00a0<strong>80<\/strong>: 41-52, 1999<\/dd>\n<dt>Kawasaki T, Mitsunaga-Nakatsubo K, Takeda K, Akasaka K and Shimada H<\/dt>\n<dd>Lim1 related homeobox gene (HpLim1) expressed in sea urchin embryos.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>41<\/strong>: 273-282, 1999<\/dd>\n<dt>Ishii M, Mitsunaga-Nakatsubo K, Kitajima T, Kusunoki S, Shimada H and Akasaka K<\/dt>\n<dd>Hbox1 and Hbox7 are involved in pattern formation in sea urchin embryos.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>41<\/strong>: 241-252, 1999<\/dd>\n<dt>Akasaka K, Nishimura A, Takata K, Mitsunaga K, Mibuka F, Ueda H, Hirose S, Tsutsui K and Shimada H<\/dt>\n<dd>Upstream element of the sea urchin arylsulfatase gene serves as an insulator.<\/dd>\n<dd><em>Cell Mol Biol<\/em>,\u00a0<strong>45<\/strong>: 555-565, 1999<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"1998\"><\/a><\/p>\n<h3>1998\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Koike H, Akasaka K, Mitsunaga-Nakatsubo K and Shimada H<\/dt>\n<dd>Proximal cis-regulatory elements of sea urchin arylsulfatase gene.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>40<\/strong>: 537-544, 1998<\/dd>\n<dt>Mitsunaga-Nakatsubo K, Akasaka K, Sakamoto N, Takata K, Matsumura Y, Kitajima T, Kusunoki S and Shimada H<\/dt>\n<dd>Differential expression of sea urchin Otx isoform (hpOtxE and HpOtxL) mRNAs during early development.<\/dd>\n<dd><em>Int J Dev Biol<\/em>,\u00a0<strong>42<\/strong>: 645-651, 1998<\/dd>\n<dt>Kiyama T, Akasaka K, Takata K, Mitsunaga-Nakatsubo K, Sakamoto N, Shimada H<\/dt>\n<dd>Structure and function of a sea urchin orthodenticle-related gene (HpOtx).<\/dd>\n<dd><em>Dev Biol<\/em>,\u00a0<strong>193<\/strong>: 139-145, 1998<\/dd>\n<dt>Mitsunaga-Nakatsubo K, Akasaka K, Akimoto Y, Akiba E, Kitajima T, Tomita M, Hirano H and Shimada H<\/dt>\n<dd>Arylsulfatase exists as non-enzymatic cell surface protein in sea urchin embryos.<\/dd>\n<dd><em>J Exp Zool<\/em>,\u00a0<strong>280<\/strong>: 220-230, 1998<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"1997\"><\/a><\/p>\n<h3>1997\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Kurokawa D, Akasaka K, Mitsunaga-Nakatsubo K and Shimada H<\/dt>\n<dd>Cloning of cyclin E cDNA of the sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>14<\/strong>: 791-794, 1997<\/dd>\n<dt>Morokuma J, Akasaka K, Mitsunaga-Nakatsubo K and Shimada H<\/dt>\n<dd>A cis-regulatory element within the 5&#8242; flanking region of arylsulfatase gene of sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>39<\/strong>: 469-476, 1997<\/dd>\n<dt>Akasaka K, Uemoto H, Wilt F, Mitsunaga-Nakatsubo K and Shimada H<\/dt>\n<dd>Oral-aboral ectoderm differentiation of sea urchin embryos is disrupted in response to calcium ionophore.<\/dd>\n<dd><em>Dev Growth Differ<\/em>,\u00a0<strong>39<\/strong>: 373-379, 1997<\/dd>\n<dt>Sakamoto N, Akasaka K, Mitsunaga-Nakatsubo K, Takata K, Nishitani T and Shimada H<\/dt>\n<dd>Two isoforms of orthodenticle-related proteins (HpOtx) bind to the enhancer element of sea urchin arylsulfatase gene.<\/dd>\n<dd><em>Dev Biol<\/em>,\u00a0<strong>181<\/strong>: 284-295, 1997<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"1996\"><\/a><\/p>\n<h3>1996\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Mitsunaga-Nakatsubo K, Yamazaki K, Hatoh-Okazaki M, Kawashita H, Okamura C, Akasaka K, Shimada H and Yasumasu I<\/dt>\n<dd>cDNA cloning of Na+, K(+)-ATPase alpha-subunit from embryos of the sea urchin, Hemicentrotus pulcherrimus.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>13<\/strong>: 833-841, 1996<\/dd>\n<dt>Sakamoto N, Akasaka K, Yamamoto T and Shimada H<\/dt>\n<dd>A triplex DNA structure of the polypyrimidine: polypurine stretch in the 5&#8242; flanking region of the sea urchin arylsulfatase gene.<\/dd>\n<dd><em>Zoolog Sci<\/em>,\u00a0<strong>13<\/strong>: 105-109, 1996<\/dd>\n<\/dl>\n<p>&nbsp;<\/p>\n<p><a name=\"1994\"><\/a><\/p>\n<h3>1994\u5e74<\/h3>\n<dl class=\"work list_first\">\n<dt>Yamamoto T, Akasaka K, Irie S and Shimada H<\/dt>\n<dd>A long polypyrimidine:polypurine sequence in 5&#8242; flanking region of arylsulfatase gene of sea urchin embryo.<\/dd>\n<dd><em>Int J Dev Biol<\/em>,\u00a0<strong>38<\/strong>: 337-344, 1994<\/dd>\n<\/dl>\n<\/div>\n","protected":false},"excerpt":{"rendered":"<p>2021 |2020 |2019 |2018 |2017 |2016&#46;&#46;&#46;<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"class_list":["post-302","page","type-page","status-publish","hentry"],"jetpack_sharing_enabled":true,"_links":{"self":[{"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/pages\/302","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/comments?post=302"}],"version-history":[{"count":12,"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/pages\/302\/revisions"}],"predecessor-version":[{"id":338,"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/pages\/302\/revisions\/338"}],"wp:attachment":[{"href":"https:\/\/smg.hiroshima-u.ac.jp\/index.php\/wp-json\/wp\/v2\/media?parent=302"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}