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Resource count: 6,594,866
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Resource Information
Miyakojima MG-20
|
| Organism |
Lotus |
| strain or clone |
Strain |
| Category |
Experimental strains |
| Resource name |
Miyakojima MG-20 |
| Availability |
Available
|
| Features |
| Taxonomy : |
Lotus japonicus
|
| Reference : |
Masaru Bamba, Seishiro Aoki, Tadashi Kajita, Hiroaki Setoguchi, Yasuyuki Watano, Shusei Sato, Takashi Tsuchimatsu (2020) Massive rhizobial genomic variation associated with partner quality in Lotus–Mesorhizobium symbiosis FEMS Microbiology Ecology 96
澤田有司 () マメ科植物の代謝システム解明を目指した質量分析プラットフォームの構築 大豆たん白質研究 13 139-144
Maekawa T, Kusakabe M, Shimoda Y, Sato S, Tabata S, Murooka Y, Hayashi M. (2008) Polyubiquitin promoter-based binary vectors for overexpression and gene silencing in Lotus japonicus. Mol Plant Microbe Interact 21(4) 375-82
Wang Y, Yang F, Zhu PF, Khan A, Xie ZP, Staehelin C. (2021) Use of the rhizobial type III effector gene nopP to improve Agrobacterium rhizogenes-mediated transformation of Lotus japonicus. Plant Methods 17(1) 66
Wang L, Liang J, Zhou Y, Tian T, Zhang B, Duanmu D. (2021) Molecular Characterization of Carbonic Anhydrase Genes in <i>Lotus japonicus</i> and Their Potential Roles in Symbiotic Nitrogen Fixation. Int J Mol Sci 22(15)
Feng Y, Wu P, Liu C, Peng L, Wang T, Wang C, Tan Q, Li B, Ou Y, Zhu H, Yuan S, Huang R, Stacey G, Zhang Z, Cao Y. (2021) Suppression of LjBAK1-mediated immunity by SymRK promotes rhizobial infection in Lotus japonicus. Mol Plant 14(11) 1935-1950
Hayashi-Tsugane M, Kawaguchi M. (2022) Lotus japonicus HAR1 regulates root morphology locally and systemically under a moderate nitrate condition in the absence of rhizobia. Planta 255(5) 95
Kikuchi Y, Hijikata N, Yokoyama K, Ohtomo R, Handa Y, Kawaguchi M, Saito K, Ezawa T. (2014) Polyphosphate accumulation is driven by transcriptome alterations that lead to near-synchronous and near-equivalent uptake of inorganic cations in an arbuscular mycorrhizal fungus. New Phytol 204(3) 638-649
Fukai E, Yoshikawa M, Shah N, Sandal N, Miyao A, Ono S, Hirakawa H, Akyol TY, Umehara Y, Nonomura KI, Stougaard J, Hirochika H, Hayashi M, Sato S, Andersen SU, Okazaki K. (2022) Widespread and transgenerational retrotransposon activation in inter- and intraspecies recombinant inbred populations of Lotus japonicus. Plant J 111(5) 1397-1410
Yusaku Noda, Jun Furukawa, Nobuo Suzui, Yong-Gen Yin, Keita Matsuoka, Naoki Kawachi, Shinobu Satoh (2022) Characterization of zinc uptake and translocation visualized with positron-emitting 65Zn tracer and analysis of transport-related gene expression in two <i>Lotus japonicus</i> accessions Annals of Botany
Yusaku Sugimura and Katsuharu Saito (2017) Comparative transcriptome analysis between Solanum lycopersicum L. and Lotus japonicus L. during arbuscular mycorrhizal development Soil Science and Plant Nutrition 63(2) 127-136
Masatsugu Hashiguchi; Rinda Puspasari; Yuya Suematsu; Melody Muguerza; Hidenori Tanaka; Akihiro Suzuki; Franz Hoffmann; Ryo Akashi (2017) Induction of tetraploid Lotus japonicus and interspecific hybridization with super-root derived Lotus corniculatus regenerants Crop Sci 57 2387–2394
Tominaga T, Miura C, Sumigawa Y, Hirose Y, Yamaguchi K, Shigenobu S, Mine A, Kaminaka H. (2021) Conservation and Diversity in Gibberellin-Mediated Transcriptional Responses Among Host Plants Forming Distinct Arbuscular Mycorrhizal Morphotypes. Front Plant Sci 12 795695
Sugiyama A, Shitan N, Sato S, Nakamura Y, Tabata S, Yazaki K. (2006) Genome-wide analysis of ATP-binding cassette (ABC) proteins in a model legume plant, Lotus japonicus: comparison with Arabidopsis ABC protein family. DNA Res 13(5) 205-28
Ono N, Ishida K, Yamashino T, Nakanishi H, Sato S, Tabata S, Mizuno T. (2010) Genomewide characterization of the light-responsive and clock-controlled output pathways in Lotus japonicus with special emphasis of its uniqueness. Plant Cell Physiol 51(10) 1800-14
Takos A, Lai D, Mikkelsen L, Abou Hachem M, Shelton D, Motawia MS, Olsen CE, Wang TL, Martin C, Rook F. (2010) Genetic screening identifies cyanogenesis-deficient mutants of Lotus japonicus and reveals enzymatic specificity in hydroxynitrile glucoside metabolism. Plant Cell 22(5) 1605-19
Sugiyama A, Linley PJ, Sasaki K, Kumano T, Yamamoto H, Shitan N, Ohara K, Takanashi K, Harada E, Hasegawa H, Terakawa T, Kuzuyama T, Yazaki K. (2011) Metabolic engineering for the production of prenylated polyphenols in transgenic legume plants using bacterial and plant prenyltransferases. Metab Eng 13(6) 629-37
Gossmann JA, Markmann K, Brachmann A, Rose LE, Parniske M. (2012) Polymorphic infection and organogenesis patterns induced by a Rhizobium leguminosarum isolate from Lotus root nodules are determined by the host genotype. New Phytol 196(2) 561-573
Ikeda Y, Shimura H, Kitahara R, Masuta C, Ezawa T. (2012) A novel virus-like double-stranded RNA in an obligate biotroph arbuscular mycorrhizal fungus: a hidden player in mycorrhizal symbiosis. Mol Plant Microbe Interact 25(7) 1005-12
Takanashi K, Sasaki T, Kan T, Saida Y, Sugiyama A, Yamamoto Y, Yazaki K. (2016) A Dicarboxylate Transporter, LjALMT4, Mainly Expressed in Nodules of Lotus japonicus. Mol Plant Microbe Interact 29(7) 584-92
Tominaga T, Miura C, Takeda N, Kanno Y, Takemura Y, Seo M, Yamato M, Kaminaka H. (2020) Gibberellin Promotes Fungal Entry and Colonization during Paris-Type Arbuscular Mycorrhizal Symbiosis in Eustoma grandiflorum. Plant Cell Physiol 61(3) 565-575
Li H, Jiang F, Wu P, Wang K, Cao Y. (2020) A High-Quality Genome Sequence of Model Legume <i>Lotus japonicus</i> (MG-20) Provides Insights into the Evolution of Root Nodule Symbiosis. Genes (Basel) 11(5)
Akamatsu A, Nagae M, Nishimura Y, Romero Montero D, Ninomiya S, Kojima M, Takebayashi Y, Sakakibara H, Kawaguchi M, Takeda N. (2021) Endogenous gibberellins affect root nodule symbiosis via transcriptional regulation of NODULE INCEPTION in Lotus japonicus. Plant J 105(6) 1507-1520
Villar I, Rubio MC, Calvo-Begueria L, Pérez-Rontomé C, Larrainzar E, Wilson MT, Sandal N, Mur LA, Wang L, Reeder B, Duanmu D, Uchiumi T, Stougaard J, Becana M. (2021) Three classes of hemoglobins are required for optimal vegetative and reproductive growth of Lotus japonicus: genetic and biochemical characterization of LjGlb2-1. J Exp Bot 72(22) 7778-7791
Du Y, Luo S, Zhao J, Feng Z, Chen X, Ren W, Liu X, Wang Z, Yu L, Li W, Qu Y, Liu J, Zhou L. (2021) Genome and transcriptome-based characterization of high energy carbon-ion beam irradiation induced delayed flower senescence mutant in Lotus japonicus. BMC Plant Biol 21(1) 510
Misawa F, Ito M, Nosaki S, Nishida H, Watanabe M, Suzuki T, Miura K, Kawaguchi M, Suzaki T. (2022) Nitrate transport via NRT2.1 mediates NIN-LIKE PROTEIN-dependent suppression of root nodulation in Lotus japonicus. Plant Cell 34(5) 1844-1862
Goto T, Soyano T, Liu M, Mori T, Kawaguchi M. (2022) Auxin methylation by <i>IAMT1</i>, duplicated in the legume lineage, promotes root nodule development in <i>Lotus japonicus</i>. Proc Natl Acad Sci U S A 119(10) e2116549119
Akamatsu A, Nagae M, Takeda N. (2022) The <i>CYCLOPS Response Element</i> in the <i>NIN</i> Promoter Is Important but Not Essential for Infection Thread Formation During <i>Lotus japonicus-</i>Rhizobia Symbiosis. Mol Plant Microbe Interact 35(8) 650-658
Yunjian Xu, Zhe Chen, Xiaoyu Li, Jing Tan, Fang Liu, Jianping Wu (2023) Mycorrhizal fungi alter root exudation to cultivate a beneficial microbiome for plant growth Functional Ecology 37 664-675
Jiao Liu, Leru Liu, Lu Tian, Shaoming Xu, Guojiang Wu, Huawu Jiang, Yaping Chen (2023) Overexpression of LjPLT3 Enhances Salt Tolerance in Lotus japonicus International Journal of Molecular Sciences 24 5149
Longlong Wang, Tao Tian, Jianjun Liang, Runhui Li, Xian Xin, Yongmei Qi, Yumiao Zhou, Qiuling Fan, Guogui Ning, Manuel Becana, Deqiang Duanmu (2023) A transcription factor of the
<scp>NAC</scp>
family regulates nitrate‐induced legume nodule senescence New Phytologist 238 2113-2129
Takanashi K, Sugiyama A, Sato S, Tabata S, Yazaki K. (2012) LjABCB1, an ATP-binding cassette protein specifically induced in uninfected cells of Lotus japonicus nodules. J Plant Physiol 169(3) 322-6
Uchiumi T, Ohwada T, Itakura M, Mitsui H, Nukui N, Dawadi P, Kaneko T, Tabata S, Yokoyama T, Tejima K, Saeki K, Omori H, Hayashi M, Maekawa T, Sriprang R, Murooka Y, Tajima S, Simomura K, Nomura M, Suzuki A, Shimoda Y, Sioya K, Abe M, Minamisawa K. (2004) Expression islands clustered on the symbiosis island of the Mesorhizobium loti genome. J Bacteriol 186(8) 2439-48
Poch HL, López RH, Clark SJ. (2007) Ecotypes of the model legume Lotus japonicus vary in their interaction phenotypes with the root-knot nematode Meloidogyne incognita. Ann Bot 99(6) 1223-9
Hiraoka Y, Ueda H, Sugimoto Y. (2009) Molecular responses of Lotus japonicus to parasitism by the compatible species Orobanche aegyptiaca and the incompatible species Striga hermonthica. J Exp Bot 60(2) 641-50
Fukai E, Dobrowolska AD, Madsen LH, Madsen EB, Umehara Y, Kouchi H, Hirochika H, Stougaard J. (2008) Transposition of a 600 thousand-year-old LTR retrotransposon in the model legume Lotus japonicus. Plant Mol Biol 68(6) 653-63
Maekawa-Yoshikawa M, Müller J, Takeda N, Maekawa T, Sato S, Tabata S, Perry J, Wang TL, Groth M, Brachmann A, Parniske M. (2009) The temperature-sensitive brush mutant of the legume Lotus japonicus reveals a link between root development and nodule infection by rhizobia. Plant Physiol 149(4) 1785-96
Tominaga A, Nagata M, Futsuki K, Abe H, Uchiumi T, Abe M, Kucho K, Hashiguchi M, Akashi R, Hirsch AM, Arima S, Suzuki A. (2009) Enhanced nodulation and nitrogen fixation in the abscisic acid low-sensitive mutant enhanced nitrogen fixation1 of Lotus japonicus. Plant Physiol 151(4) 1965-76
Ichida H, Yoneyama K, Koba T, Abe T. (2009) Epigenetic modification of rhizobial genome is essential for efficient nodulation. Biochem Biophys Res Commun 389(2) 301-4
Ueoka-Nakanishi H, Hori N, Ishida K, Ono N, Yamashino T, Nakamichi N, Mizuno T. (2011) Characterization of shade avoidance responses in Lotus japonicus. Biosci Biotechnol Biochem 75(11) 2148-54
Shigeyama T, Tominaga A, Arima S, Sakai T, Inada S, Jikumaru Y, Kamiya Y, Uchiumi T, Abe M, Hashiguchi M, Akashi R, Hirsch AM, Suzuki A. (2012) Additional cause for reduced JA-Ile in the root of a Lotus japonicus phyB mutant. Plant Signal Behav 7(7) 746-8
Kimura M, Cutler S, Isobe S. (2015) A Novel Phenolic Compound, Chloroxynil, Improves Agrobacterium-Mediated Transient Transformation in Lotus japonicus. PLoS One 10(7) e0131626
Nambu M, Tatsukami Y, Morisaka H, Kuroda K, Ueda M. (2015) Quantitative time-course proteome analysis of Mesorhizobium loti during nodule maturation. J Proteomics 125 112-20
Osuki KI, Hashimoto S, Suzuki A, Araragi M, Takahara A, Kurosawa M, Kucho KI, Higashi S, Abe M, Uchiumi T. (2016) Gene expression and localization of a β-1,3-glucanase of Lotus japonicus. J Plant Res 129(4) 749-758
Sugiyama A, Saida Y, Yoshimizu M, Takanashi K, Sosso D, Frommer WB, Yazaki K. (2017) Molecular Characterization of LjSWEET3, a Sugar Transporter in Nodules of Lotus japonicus. Plant Cell Physiol 58(2) 298-306
Kawaguchi M, Imaizumi-Anraku H, Koiwa H, Niwa S, Ikuta A, Syono K, Akao S. (2002) Root, root hair, and symbiotic mutants of the model legume Lotus japonicus. Mol Plant Microbe Interact 15(1) 17-26
Nishimura R, Hayashi M, Wu GJ, Kouchi H, Imaizumi-Anraku H, Murakami Y, Kawasaki S, Akao S, Ohmori M, Nagasawa M, Harada K, Kawaguchi M. (2002) HAR1 mediates systemic regulation of symbiotic organ development. Nature 420(6914) 426-9
Asamizu E, Nakamura Y, Sato S, Tabata S. (2004) Characteristics of the Lotus japonicus gene repertoire deduced from large-scale expressed sequence tag (EST) analysis. Plant Mol Biol 54(3) 405-14
Imaizumi-Anraku H, Takeda N, Charpentier M, Perry J, Miwa H, Umehara Y, Kouchi H, Murakami Y, Mulder L, Vickers K, Pike J, Downie JA, Wang T, Sato S, Asamizu E, Tabata S, Yoshikawa M, Murooka Y, Wu GJ, Kawaguchi M, Kawasaki S, Parniske M, Hayashi M. (2005) Plastid proteins crucial for symbiotic fungal and bacterial entry into plant roots. Nature 433(7025) 527-31
Holligan D, Zhang X, Jiang N, Pritham EJ, Wessler SR. (2006) The transposable element landscape of the model legume Lotus japonicus. Genetics 174(4) 2215-28
Ichida H, Matsuyama T, Abe T, Koba T. (2007) DNA adenine methylation changes dramatically during establishment of symbiosis. FEBS J 274(4) 951-62
Udvardi MK, Tabata S, Parniske M, Stougaard J. (2005) Lotus japonicus: legume research in the fast lane. Trends Plant Sci 10(5) 222-8
Sandal N, Petersen TR, Murray J, Umehara Y, Karas B, Yano K, Kumagai H, Yoshikawa M, Saito K, Hayashi M, Murakami Y, Wang X, Hakoyama T, Imaizumi-Anraku H, Sato S, Kato T, Chen W, Hossain MS, Shibata S, Wang TL, Yokota K, Larsen K, Kanamori N, Madsen E, Radutoiu S, Madsen LH, Radu TG, Krusell L, Ooki Y, Banba M, Betti M, Rispail N, Skøt L, Tuck E, Perry J, Yoshida S, Vickers K, Pike J, Mulder L, Charpentier M, Müller J, Ohtomo R, Kojima T, Ando S, Marquez AJ, Gresshoff PM, Harada K, Webb J, Hata S, Suganuma N, Kouchi H, Kawasaki S, Tabata S, Hayashi M, Parniske M, Szczyglowski K, Kawaguchi M, Stougaard J. (2006) Genetics of symbiosis in Lotus japonicus: recombinant inbred lines, comparative genetic maps, and map position of 35 symbiotic loci. Mol Plant Microbe Interact 19(1) 80-91
Feng X, Zhao Z, Tian Z, Xu S, Luo Y, Cai Z, Wang Y, Yang J, Wang Z, Weng L, Chen J, Zheng L, Guo X, Luo J, Sato S, Tabata S, Ma W, Cao X, Hu X, Sun C, Luo D. (2006) Control of petal shape and floral zygomorphy in Lotus japonicus. Proc Natl Acad Sci U S A 103(13) 4970-5
Nukui N, Minamisawa K, Ayabe S, Aoki T. (2006) Expression of the 1-aminocyclopropane-1-carboxylic acid deaminase gene requires symbiotic nitrogen-fixing regulator gene nifA2 in Mesorhizobium loti MAFF303099. Appl Environ Microbiol 72(7) 4964-9
Sasakura F, Uchiumi T, Shimoda Y, Suzuki A, Takenouchi K, Higashi S, Abe M. (2006) A class 1 hemoglobin gene from Alnus firma functions in symbiotic and nonsymbiotic tissues to detoxify nitric oxide. Mol Plant Microbe Interact 19(4) 441-50
Nakatsukasa-Akune M, Yamashita K, Shimoda Y, Uchiumi T, Abe M, Aoki T, Kamizawa A, Ayabe S, Higashi S, Suzuki A. (2005) Suppression of root nodule formation by artificial expression of the TrEnodDR1 (coat protein of White clover cryptic virus 1) gene in Lotus japonicus. Mol Plant Microbe Interact 18(10) 1069-80
Akihiro Suzuki, Hisatoshi Hara, Tomoyo Kinoue, Mikiko Abe, Toshiki Uchiumi, Ken-ichi Kucho, Shiro Higashi, Ann M. Hirsch and Susumu Arima (2008) Split-root study of autoregulation of nodulation in the model legume Lotus japonicus J Plant Res. 121 (2)
Shimada N, Sato S, Akashi T, Nakamura Y, Tabata S, Ayabe S, Aoki T. (2007) Genome-wide analyses of the structural gene families involved in the legume-specific 5-deoxyisoflavonoid biosynthesis of Lotus japonicus. DNA Res 14(1) 25-36
Sato S, Nakamura Y, Kaneko T, Asamizu E, Kato T, Nakao M, Sasamoto S, Watanabe A, Ono A, Kawashima K, Fujishiro T, Katoh M, Kohara M, Kishida Y, Minami C, Nakayama S, Nakazaki N, Shimizu Y, Shinpo S, Takahashi C, Wada T, Yamada M, Ohmido N, Hayashi M, Fukui K, Baba T, Nakamichi T, Mori H, Tabata S. (2008) Genome structure of the legume, Lotus japonicus. DNA Res 15(4) 227-39
Wang X, Sato S, Tabata S, Kawasaki S. (2008) A high-density linkage map of Lotus japonicus based on AFLP and SSR markers. DNA Res 15(5) 323-32
S. Okazaki, S. Okabe, M. Higashi, Y. Shimoda, S. Sato, S. Tabata, M. Hashiguchi, R. Akashi and K. Saeki. (2009) Identification and functional analysis of type III effector proteins in Mesorhizobium loti. Molecular Plant-Microbe Interaction
Ueda H, Sugimoto Y. (2010) Vestitol as a chemical barrier against intrusion of parasitic plant Striga hermonthica into Lotus japonicus roots. Biosci Biotechnol Biochem 74(8) 1662-7
Hijikata N, Murase M, Tani C, Ohtomo R, Osaki M, Ezawa T. (2010) Polyphosphate has a central role in the rapid and massive accumulation of phosphorus in extraradical mycelium of an arbuscular mycorrhizal fungus. New Phytol 186(2) 285-9
Murakami E, Nagata M, Shimoda Y, Kucho K, Higashi S, Abe M, Hashimoto M, Uchiumi T. (2011) Nitric oxide production induced in roots of Lotus japonicus by lipopolysaccharide from Mesorhizobium loti. Plant Cell Physiol 52(4) 610-7
Kai S, Tanaka H, Hashiguchi M, Iwata H, Akashi R (2010) Analysis of genetic diversity and morphological traits of Japanese Lotus japonicus for establishment of a core collection Breed Sci. 60(4) 436-446
Quazi Forhad Quadira, Toshihiro Watanabeb, Zheng Chena, Mitsuru Osakib, Takuro Shinanoc (2011) Ionomic response of Lotus japonicus to different root-zone temperatures Soil Science and Plant Nutrition 57(2) 221-232
Masatsugu Hashiguchi, Shin-ichi Tsuruta, Ryo Akashi (2011) Morphological Traits of Lotus japonicus (Regal) Ecotypes Collected in Japan IBC 3(4) 1-7
Yamashino T, Yamawaki S, Hagui E, Ishida K, Ueoka-Nakanishi H, Nakamichi N, Mizuno T. (2013) Clock-controlled and FLOWERING LOCUS T (FT)-dependent photoperiodic pathway in Lotus japonicus II: characterization of a microRNA implicated in the control of flowering time. Biosci Biotechnol Biochem 77(6) 1179-85
Van de Velde W, Zehirov G, Szatmari A, Debreczeny M, Ishihara H, Kevei Z, Farkas A, Mikulass K, Nagy A, Tiricz H, Satiat-Jeunemaître B, Alunni B, Bourge M, Kucho K, Abe M, Kereszt A, Maroti G, Uchiumi T, Kondorosi E, Mergaert P. (2010) Plant peptides govern terminal differentiation of bacteria in symbiosis. Science 327(5969) 1122-6
Tatsukami Y, Nambu M, Morisaka H, Kuroda K, Ueda M. (2013) Disclosure of the differences of Mesorhizobium loti under the free-living and symbiotic conditions by comparative proteome analysis without bacteroid isolation. BMC Microbiol 13 180
Takanashi K, Yokosho K, Saeki K, Sugiyama A, Sato S, Tabata S, Ma JF, Yazaki K. (2013) LjMATE1: a citrate transporter responsible for iron supply to the nodule infection zone of Lotus japonicus. Plant Cell Physiol 54(4) 585-94
Amin AN, Hayashi S, Bartlem DG. (2014) Robust in vitro assay system for quantitative analysis of parasitic root-knot nematode infestation using Lotus japonicus. J Biosci Bioeng 118(2) 205-13
Katsuyuki Yanagi , Koichi Sugimoto & Kenji Matsui (2011) Oxylipin-specific cytochrome P450s (CYP74s) in Lotus japonicus: their implications in response to mechanical wounding and nodule formation J Plant Interactions Volume 6, Issue 4 255-264
Ying Cheng, Keiko Ishimoto, Yuko Kuriyama, Mitsuru Osaki, Tatsuhiro Ezawa (2012) Ninety-year-, but not single, application of phosphorus fertilizer has a major impact on arbuscular mycorrhizal fungal communities Plant Soil Volume 365, Issue 1-2 397-407
Makiko Mimura (2013) Genetic and phenotypic variation in Lotus japonicus (Regel) K. Larsen, a model legume species Canadian Journal of Plant Science Vol. 93, No. 3 435-444
Xiaoyu Li, Ying Cheng, Wei Ma, Yang Zhao, Haiyang Jiang, Ming Zhang (2010) Identification and characterization of NBS-encoding disease resistance genes in Lotus japonicus Plant Syst Evol Volume 289, Issue 1-2 101-110
Kojima T, Saito K, Oba H, Yoshida Y, Terasawa J, Umehara Y, Suganuma N, Kawaguchi M, Ohtomo R. (2014) Isolation and phenotypic characterization of Lotus japonicus mutants specifically defective in arbuscular mycorrhizal formation. Plant Cell Physiol 55(5) 928-41
Hideki Hirakawa, Terry Mun, Shusei Sato, Stig U. Andersen (2014) Legume and Lotus japonicus Databases The Lotus japonicus Genome IV 259-267
Hidenori Tanaka, Awatsaya Chotekajorn, Sayumi Kai, Genki Ishigaki, Masatsugu Hashiguchi, Ryo Akashi (2016) Determination of Genome Size, Chromosome Number, and Genetic Variation Using Inter-Simple Sequence Repeat Markers in Lotus spp. Cytologia 81(1) 95-102
Lai D, Pičmanová M, Abou Hachem M, Motawia MS, Olsen CE, Møller BL, Rook F, Takos AM. (2015) Lotus japonicus flowers are defended by a cyanogenic β-glucosidase with highly restricted expression to essential reproductive organs. Plant Mol Biol 89(1-2) 21-34
Sugiyama A, Fukuda S, Takanashi K, Yoshioka M, Yoshioka H, Narusaka Y, Narusaka M, Kojima M, Sakakibara H, Shitan N, Sato S, Tabata S, Kawaguchi M, Yazaki K. (2015) Molecular Characterization of LjABCG1, an ATP-Binding Cassette Protein in Lotus japonicus. PLoS One 10(9) e0139127
Nagata M, Yamamoto N, Shigeyama T, Terasawa Y, Anai T, Sakai T, Inada S, Arima S, Hashiguchi M, Akashi R, Nakayama H, Ueno D, Hirsch AM, Suzuki A. (2015) Red/Far Red Light Controls Arbuscular Mycorrhizal Colonization via Jasmonic Acid and Strigolactone Signaling. Plant Cell Physiol 56(11) 2100-9
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