Aug. 2011, 日本土壌肥料学会奨励賞

Jul. 2010, RADIOISOTOPES誌論文奨励賞

Search for Expression Marker Genes That Reflect the Physiological Conditions of Blossom End Enlargement Occurrence in Cucumber
Rui Li; Runewa Atarashi; Agung Dian Kharisma; Nur Akbar Arofatullah; Yuki Tashiro; Junjira Satitmunnaithum; Sayuri Tanabata; Kenji Yamane; Tatsuo Sato, Blossom end enlargement (BEE) is a postharvest deformation that may be related to the influx of photosynthetic assimilates before harvest. To elucidate the mechanism by which BEE occurs, expression marker genes that indicate the physiological condition of BEE-symptomatic fruit are necessary. First, we discovered that preharvest treatment with a synthetic cytokinin, N-(2-Chloro-4-pyridyl)-N’-phenylurea (CPPU), promoted fruit growth and suppressed BEE occurrence. This suggests that excessive assimilate influx is not a main cause of BEE occurrence. Subsequently, the expression levels of seven sugar-starvation marker genes, CsSEF1, AS, CsFDI1, CsPID, CsFUL1, CsETR1, and CsERF1B, were compared among symptomatic and asymptomatic fruits, combined with and without CPPU treatment. Only CsSEF1 showed a higher expression level in asymptomatic fruits than in symptomatic fruits, regardless of CPPU treatment. This was then tested using fruits stored via the modified-atmosphere packaging technique, which resulted in a lower occurrence of BEE, and the asymptomatic fruits showed a higher CsSEF1 expression level than symptomatic fruits, regardless of the packaging method. CsSEF1 codes a CCCH-type zinc finger protein, and an increase in the expression of CsSEF1 was correlated with a decrease in the fruit respiration rate. Thus, CsSEF1 may be usable as a BEE expression marker gene., MDPI AG
International Journal of Molecular Sciences, 30 Jul. 2024, [Reviewed]

Ultraviolet-B Irradiation Induces Resistance against Powdery Mildew in Cucumber (Cucumis sativus L.) through a Different Mechanism Than That of Heat Shock-Induced Resistance
Dinar Mindrati Fardhani; Agung Dian Kharisma; Tomoyuki Kobayashi; Nur Akbar Arofatullah; Makoto Yamada; Sayuri Tanabata; Yumi Yokoda; Ani Widiastuti; and Tatsuo Sato, MDPI
Agronomy, 29 Nov. 2022, [Reviewed]

Effects of Application of Various forms of Nitrogen on the Growth of Soybean Nodules and Roots Related to the Carbon and Nitrogen Metabolism
Takuji Ohyama; Sayuri Tanabata; Norikuni Ohtake; Takashi Sato; Kuni Sueyoshi; Yoshihiko Takahashi; Shinji Ishikawa; Yuki Ono; Natsumi Yamashita; Akinori Saito, Soybean plants require a large amount of nitrogen either from nitrogen fixation in nodules or nitrogen absorption from roots. It is known that nitrate, a major inorganic nitrogen compound in upland soils, represses nodule growth and nitrogen fixation. Rapid and reversible inhibition of nodule growth and nitrogen fixation activity was found in the hydroponically cultivated soybeans after changing the nutrient solution with or without nitrate. Isotope tracer analysis revealed that the major cause of this inhibition depended on the changes in the partitioning of photo-assimilate between nodules and roots and was not directly related to the transported N compounds. Transcriptome and metabolome analyses supported that nitrate strongly promotes nitrogen and carbon metabolism in the roots but represses them in the nodules. The application of ammonium, glutamine, or urea also inhibited the nodule growth and nitrogen fixation like nitrate, although the inhibition was lower than that of nitrate. The degree of inhibition was related to the decrease in carbon isotope partitioning into the nodules, rather than the import of nitrogen isotope to nodules. Urea was detected in xylem sap and all parts of soybean, and some urea might be originated from ureide degradation., IntechOpen
Soybean - Recent Advances in Research and Applications, 28 Sep. 2022

Cultivation Conditions Affect the Occurrence of Blossom-end Enlargement in Cucumber
Junjira Satitmunnaithum; Hikaru Muroi; Rina Ito; Yuki Tashiro; Antonius Febri Hendratmo; Sayuri Tanabata and Tatsuo Sato, The Japanese Society for Horticultural Science
The Horticulture Journal, 02 Aug. 2022, [Reviewed]

Microbial population size and strawberry fruit firmness after drop shock-induced mechanical damage
Junjira Satitmunnaithum; Hiroaki Kitazawa; Nur Akbar Arofatullah; Ani Widiastuti; Agung Dian Kharisma; Kenji Yamane; Sayuri Tanabata; Tatsuo Sato, Elsevier
Postharvest Biology and Technology, 14 Jun. 2022, [Reviewed]

Regulation of defense responses via heat shock transcription factors in Cucumis sativus L. against Botrytis cinerea
Kharisma A.D.; Arofatullah N.A.; Yamane K.; Tanabata S. and Sato T., Springer
Journal of General Plant Pathology, 12 Nov. 2021, [Reviewed]

Case Study on the Use of the Leaf-Count Method for Drip Fertigation in Outdoor Cucumber Cultivation in Reconstructed Fields Devastated by a Tsunami
Tashiro Y.; Sato S.; Satitmunnaithum J.; Kinouchi H.; Li J. and Tanabata S., MDPI
Agriculture, 11 Jul. 2021, [Reviewed]

Application of Nitrate, Ammonium, or Urea Changes the Concentrations of Ureides, Urea, Amino Acids and Other Metabolites in Xylem Sap and in the Organs of Soybean Plants (Glycine max (L.) Merr.)
Yuki Ono; Masashige Fukasawa; Kuni Sueyoshi; Norikuni Ohtake; Takashi Sato; Sayuri Tanabata; Ryo Toyota; Kyoko Higuchi; Akihiro Saito and Takuji Ohyama, Soybean (Glycine max (L.) Merr.) plants form root nodules and fix atmospheric dinitrogen, while also utilizing the combined nitrogen absorbed from roots. In this study, nodulated soybean plants were supplied with 5 mM N nitrate, ammonium, or urea for 3 days, and the changes in metabolite concentrations in the xylem sap and each organ were analyzed. The ureide concentration in the xylem sap was the highest in the control plants that were supplied with an N-free nutrient solution, but nitrate and asparagine were the principal compounds in the xylem sap with nitrate treatment. The metabolite concentrations in both the xylem sap and each organ were similar between the ammonium and urea treatments. Considerable amounts of urea were present in the xylem sap and all the organs among all the treatments. Positive correlations were observed between the ureides and urea concentrations in the xylem sap as well as in the roots and leaves, although no correlations were observed between the urea and arginine concentrations, suggesting that urea may have originated from ureide degradation in soybean plants, possibly in the roots. This is the first finding of the possibility of ureide degradation to urea in the underground organs of soybean plants., MDPI
International Journal of Molecular Sciences, Apr. 2021, [Reviewed]

Hot Water Spray Over Strawberry Plants Effectively Controls the Occurrence of Strawberry Powdery Mildew in Everbearing Strawberry Production
Dinar Mindrati FARDHANI; Yuuki OHTA; Nur Akbar AROFATULLAH; Agung Dian KHARISMA; Junjira SATITMUNNAITHUM; Sayuri TANABATA; Isao OGIWARA; Ani WIDIASTUTI and Tatsuo SATO, Japanese Society of Farm Work Research
Japanese Journal of Farm Work Research, Mar. 2021, [Reviewed]

Effect of Intact Lateral Shoot Leaves Just below the Fruit Truss on Photoassimilate Translocation to Tomato Fruit Using a Positron-emitting Tracer Imaging System
Takashi Tsukamoto, Satomi Ishii, Sayuri Tanabata, Nobuo Suzui, Naoki Kawachi, Shu Fujimaki and Tomoyuki Kusakawa, 園芸学会
園芸学研究, Jul. 2020, [Reviewed]

Prevention of powdery mildew disease in tomato nursery by improved hot water spraying device　　　　　　　　　　　　　　　
Nur Akbar Arofatullah; Ani Widiastuti; Yufita Dwi Chinta; Tomoyuki Kobayashi; Sayuri Tanabata and Tatsuo Sato
Japanese Journal of Farm Work Research, Jun. 2019, [Reviewed]

Effects of Different Chemical Forms of Nitrogen on the Quick and Reversible Inhibition of Soybean Nodule Growth and Nitrogen Fixation Activity
Natsumi Yamashita†; Sayuri Tanabata†; Norikuni Ohtake; Kuni Sueyoshi; Takashi Sato; Kyoko Higuchi; Akihiro Saito and Takuji Ohyama, Lead, It has been reported that supply of nitrate to culture solution rapidly and reversibly inhibits nodule growth and nitrogen fixation activity of soybean. In this study, the effects of ammonium, urea, or glutamine on nodule growth and nitrogen fixation activity are compared with that for nitrate. Soybean plants were cultivated with a nitrogen-free nutrient solution, then 1 mM-N of nitrate, ammonium, glutamine, or urea were supplied from 12 DAP until 17 DAP. Repression of nodule growth and nitrogen fixation activity at 17 DAP were observed by ammonium, urea, and glutamine like nitrate, although the inhibitory effects were milder than nitrate. The removal of nitrogen from the culture solutions after nitrogen treatments resulted in a recovery of the nodule growth. It was found that the glutamine treatment followed by N-free cultivation gave highest nitrogen fixation activity about two times of the control. Tracer experiments with 15N and 13C were performed to evaluate the translocation of N and C to the different tissues. Culture solutions containing a 15N-labeled nitrogen source were supplied from 21 DAP, and the whole shoots were exposed to 13CO2 for 60 min on 23 DAP, and plants were harvested on 24 DAP. The percentage distribution of 15N in nodules was highest for ammonium (1.4%) followed by glutamine (0.78%), urea (0.32%) and nitrate (0.25%). The percentage distribution of 13C in the nodules was highest for the control (11.5%) followed by urea (5.8%), glutamine (2.6%), ammonium (2.3%), and nitrate (2.3%). The inhibitory effects of nitrogen compounds appeared to be related to a decrease in photoassimilate partitioning in the nodules, rather than 15N transport into the nodules. The free amino acid concentrations after nitrogen treatments were increased in the nodules and leaves by nitrate, in the roots by ammonium, in the stems by urea, and the roots, stems, and leaves by glutamine treatment. The concentrations of asparagine, aspartate, and glutamine were increased after nitrogen treatments. By the long-term supply of nitrogen for 2-weeks, nitrate significantly increased the lateral roots and leaf growth. The long-term supply of urea and glutamine also promoted the lateral roots and leaf growth, but ammonium suppressed them.
Frontiers in Plant Science, 19 Feb. 2019, [Reviewed]

Effect of the Nitrification Inhibitor 3,4-Dimethylpyrazole Phosphate on the Deep Placement of Nitrogen Fertilizers for Soybean Cultivation
Soshi Hatano; Yoichi Fujita; Yoshifumi Nagumo; Norikuni Ohtake; Kuni Sueyoshi; Yoshihiko Takahashi; Takashi Sato; Sayuri Tanabata; Kyoko Higuchi; Akihiro Saito and Takuji Ohyama
International Journal of Agronomy, 03 Feb. 2019, [Reviewed]

Heat Shock-Induced Resistance against Pseudomonas syringae pv. tomato (Okabe) Young et al. via Heat Shock Transcription Factors in Tomato
Nur Akbar Arofatullah; Morifumi Hasegawa; Sayuri Tanabata; Isao Ogiwara and Tatsuo Sato, *Abstract: We investigated the role of heat shock transcription factors (Hsfs) during induction of defense response by heat-shock treatment (HST) in tomato. Leaf disease symptoms were significantly reduced at 12 and 24 h after HST, consistent with upregulation of pathogenesis-related (PR) genes PR1a2 and PR1b1 peaking at 24 h after treatment. These genes were upregulated at the treatment application site, but not in untreated leaves. In contrast to HST, inoculation of the first leaf induced systemic upregulation of acidic PR genes in uninoculated second leaves. Furthermore, heat shock element motifs were found in upstream regions of PR1a2, PR1b1, Chitinase 3, Chitinase 9, Glucanase A, and Glucanase B genes. Upregulation of HsfA2 and HsfB1 peaked at 6 h after HST, 6 h earlier than salicylic acid accumulation. Foliar spray of heat shock protein 90 (Hsp90) inhibitor geldanamycin (GDA) induced PR gene expression comparable to that after HST. PR gene expression and defense response against Pseudomonas syringae pv. tomato (Pst) decreased when combining HST with Hsfs inhibitor KRIBB11. The Hsfs and PR gene expression induced by heat or GDA, together with the suppression of heat shock-induced resistance (HSIR) against Pst by KRIBB11, suggested a direct contribution of Hsfs to HSIR regulation in tomato., MDPI AG
Agronomy, 20 Dec. 2018, [Reviewed]

Transcriptome and Metabolome Analyses Reveal That Nitrate Strongly Promotes Nitrogen and Carbon Metabolism in Soybean Roots, but Tends to Repress It in Nodules
Ishikawa S.; Ono Y.; Ohtake N.; Sueyoshi K.; Tanabata S. and Ohyama T., MDPI AG
Plants, 12 Apr. 2018, [Reviewed]

Evaluation of the effects and the inhibition of subcritical water on growth of green oak choi (Brassica rapa var. chinensis)
Shinjiro Oike; Sayuri Tanabata; Chika Suzuki; Kiyoshi Ozawa; Shunrokuro Fujiwara, 生態工学会
Eco-Engineering, Feb. 2017, [Reviewed]

Application of glutathione and dithiothreitol to oil seed rape (Brassica napus L.) roots affects cadmium distribution in roots and inhibits Cd translocation to shoots
Shin-ichi Nakamura; Nobuo Suzui; Sayuri Ito-Tanabata; Satomi Ishii; Naoki Kawachi; Hiroki Rai; Hiroyuki Hattori; Shu Fujimaki, Taylor and Francis Ltd.
Soil Science and Plant Nutrition, 03 Jul. 2016, [Reviewed]

Effect of Nitrate on Nodule and Root Growth of Soybean (Glycine max (L.) Merr.)
Saito A.†; Tanabata S.†; Tanabata T.; Tajima S.; Ueno M.; Ishikawa S.; Ohtake N.; Sueyoshi K. and Ohyama T.
International Journal of Molecular Sciences, Mar. 2014, [Reviewed]

Temperature affects N and C assimilation and translocation in Curcuma alismatifolia Gagnep
T. Khuankaew; S. Tanabata; M. Yamamoto; S. Ishikawa; K. Tsutsumi; N. Ohtake; K. Sueyoshi; T. Ohyama; T. Sato; C. Anuwong; S. Ruamrungsri, Headley Brothers Ltd
Journal of Horticultural Science and Biotechnology, 2014

Computational image analysis method for measuring size of nodule growth in soybean
Sayuri TANABATA; Takanari TANABATA; Akinori SAITO; Seiya TAJIMA; Shiori WATANABE; Keisuke ISHIKAWA; Norikuni OHTAKE; Kuni SUEYOSHI; Takuji OHYAMA
Japanese Journal of Soil Science and Plant Nutrition, 2014, [Reviewed]

A kinetic analysis of cadmium accumulation in a Cd hyper-accumulator fern, Athyrium yokoscense and tobacco plants.
Yoshihara T.; Suzui N.; Ishii S.; Kitazaki M.; Yamazaki H.; Kitazaki K.; Kawachi N.; Yin Y.G.; Ito-Tanabata S.; Hashida S.; Shoji K.; Shimada H.; Goto F. and Fujimaki S.
Plant, Cell and Environment, 2014, [Reviewed]

Application of glutathione to roots selectively inhibits cadmium transport from roots to shoots in oilseed rape.
Nakamura S.; Suzui N.; Nagasaka T.; Komatsu F.; Ishioka S.N.; Ito-Tanabata S.; Kawachi N.; Rai H.; Hattori H.; Chino M. and Fujimaki S.
Journal of Experimental Botany, 2013, [Reviewed]

Real-time whole-plant imaging of C-11 translocation using positron-emitting tracer imaging system
Naoki Kawachi; Nobuo Suzui; Satomi Ishii; Sayuri Ito; Noriko S. Ishioka; Haruaki Yamazaki; Aya Hatano-Iwasaki; Ken'ichi Ogawa; Shu Fujimaki
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT, Aug. 2011, [Reviewed]

Nitrogen and carbon translocation and distribution in curcuma alismatifolia gagnep. by labelling experiment with 15N and 13C
T. Khuankaew; S. Ito; N. Ohtake; K. Sueyoshi; T. Ohyama; T. Sato; S. Ruamrungsri, International Society for Horticultural Science
Acta Horticulturae, 31 Jan. 2011

Real-time imaging and analysis of differences in cadmium dynamics in rice cultivars (Oryza sativa) using positron-emitting ¹⁰⁷Cd tracer.
Ishikawa S.; Suzui N.; Ito-Tanabata S.; Ishii S.; Igura M.; Abe T.; Kuramata M.; Kawachi N. and Fujimaki S.
BMC Plant Biology, 2011, [Reviewed]

Real-time AnaIysis of TransIocation of Photosynthates to NoduIes in Soybean PIants Using 11CO2 with a Positron-emitting Tracer Imaging System (PETIS)
Sayuri lto; Nobuo Suzui; Naoki Kawavhi; Satomi lshii; NorikoIshioka and Shu Fujimaki, 日本アイソトープ協会
RADIOISOTOPES, 2010, [Reviewed]

Assimilation and translocation of nitrogen and carbon in Curcuma alismatifolia Gagnep.
Khuankaew T.; Ruamrangsri S.; Ito S.; Sato T.; Ohtake N.; Sueyoshi K. and Ohyama T.
Plant Biology, 2010, [Reviewed]

Tracing cadmium from culture to spikelet: non-invasive imaging and quantitative characterization of absorption, transport and accumulation of cadmium in an intact rice plant.
Fujimaki S.; Suzui N.; Ishioka S.N.; Kawachi N.; Ito S.; Chino M. and Nakamura S.
Plant Physiology, 2010, [Reviewed]

Molecular Imaging for Plant Physiology: Imaging of Carbon Trans location to Sink Organs
N. Kawachi; N. Suzui; S. Ishii; S. Ito; N. S. Ishioka; K. Kikuchi; T. Tsukamoto; T. Kusakawa; F. Fujimaki
2009 IEEE NUCLEAR SCIENCE SYMPOSIUM CONFERENCE RECORD, VOLS 1-5, 2009, [Reviewed]

Carbon and nitrogen transport during grain filling in rice under high-temperature conditions.
Ito S.; Hara T.; Kawanami Y.; Watanabe T.; Thiraporn K.; Ohtake N.; Sueyoshi K.; Mitsui T.; Fukuyama T.; Takahashi Y.; Sato T.; Sato A. and Ohyama T.
Journal of Agronomy and Crop Science, 2009, [Reviewed]

Real-time imaging of nitrogen fixation in an intact soybean plant with nodules using ¹³N-labeled nitrogen gas.
Ishii S.; Suzui N.; Ito S.; Ishioka S. N.; Kawachi N.; Ohtake N.; Ohyama T. and Fujimaki S.
Soil Science and Plant Nutrition, 2009, [Reviewed]

MECHANISM OF QUICK AND REVERSIBLE INHIBITION OF SOYBEAN NODULE GROWTH AND NITROGEN FIXATION ACTIVITY BY NITRATE AND ITS METABOLITES
T. Ohyama; A. Yamazaki; N. Yamashita; T. Kimura; S. Ito; N. Ohtake; K. Sueyoshi
BIOLOGICAL NITROGEN FIXATION: TOWARDS POVERTY ALLEVIATION THROUGH SUSTAINABLE AGRICULTURE, 2008, [Reviewed]

COMPARISON OF LEAF GROWTH OF HYPERNODULATION SOYBEAN MUTANTS, NOD1-3, NOD2-4 AND NOD3-7, WITH THEIR PARENT CV. WILLIAMS
S. Ito; N. Ohtake; K. Sueyoshi; T. Ohyama
BIOLOGICAL NITROGEN FIXATION: TOWARDS POVERTY ALLEVIATION THROUGH SUSTAINABLE AGRICULTURE, 2008, [Reviewed]

The autoregulation of nodulation mechanism is related to leaf development.
Ito S.; Kato T.; Ohtake N.; Sueyoshi K. and Ohyama T.
Plant and Cell Physiology, Jan. 2008, [Reviewed]

Characteristics of initial growth of hypernodulation soybean mutants, NOD1-3, NOD2-4 and NOD3-7, affected by inoculation of bradyrhizobia and nitrate supply.
Ito S.; Ohtake N.; Sueyoshi K. and Ohyama T.
Soil Science and Plant Nutrition, 2007, [Reviewed]

Effect of deep placement of slow-release fertilizer (Lime nitrogen) applied at different rates on growth, N-2 fixation and yield of soya bean (Glycine max [L.] Merr.)
T. Kaushal; M. Onda; S. Ito; A. Yamazaki; H. Fujikake; N. Ohtake; K. Sueyoshi; Y. Takahashi; T. Ohyama
JOURNAL OF AGRONOMY AND CROP SCIENCE, Dec. 2006, [Reviewed]

Mechanism of Nitrate Inhibition on Nodule Growth and Nitrogen Fixation of Soybean
OHYAMA Takuji; ITO Sayuri; OHTAKE Norikuni; SUEYOSHI Kuni, Japan Society for Bioscience, Biotechnology, and Agrochemistry
KAGAKU TO SEIBUTSU, 01 Nov. 2006

Comparison of the depth of placement of lime nitrogen on growth, N-2 fixation activity, seed yield and quality of soybean (Glycine max (L.) Merr.) plants
Tewari Kaushal; Masaru Onda; Sayuri Ito; Akihiko Yamazaki; Hiroyuki Fujikake; Norikuni Ohtake; Kuni Sueyoshi; Yoshihiko Takahashi; Yoshifumi Nagumo; Tohru Tsuchida; Takuji Ohyama
SOIL SCIENCE AND PLANT NUTRITION, Aug. 2006, [Reviewed]

Allocation of photosynthetic products in soybean during the early stages of nodule formation.
Ito S.; Ohtake N.; Sueyoshi K. and Ohyama T.
Soil Science and Plant Nutrition, 2006, [Reviewed]

Effect of nitrogen supply on nitrogen and carbohydrate constituent accumulation in rhizomes and storage root of Curcuma alismatifolia Gagnep.
Ohtake N.; Ruamrungsri S.; Ito S.; Sueyoshi K.; Ohyama T. and Apavatjrut P.
Soil Science and Plant Nutrition, 2006, [Reviewed]

Long-term effect of nitrate application from lower part of roots on nodulation and N-2 fixation in upper part of roots of soybean (Glycine max (L.) Merr.) in two-layered pot experiment
H Yashima; H Fujikake; A Yamazaki; S Ito; T Sato; K Tewari; N Ohtake; K Sueyoshi; Y Takahashi; T Ohyama
SOIL SCIENCE AND PLANT NUTRITION, Dec. 2005, [Reviewed]

¹⁵N analysis of the promotive effect of deep placement of slow-release N fertilizers on growth and seed yield of soybean.
Kaushal T.; Onda M.; Ito S.; Yamazaki A.; Fujikake H.; Ohtake N.; Sueyoshi K.; Takahashi Y. and Ohyama T.
Soil Science and Plant Nutrition, 2005, [Reviewed]

Quantitative and isotopic analysis of amino acids, allantoin, and allantoic acid in soybeans by LC-MS using the atmospheric pressure chemical ionization method.
Ohtake N.; Takano A.; Ito S.; Yamazaki A.; Fujikake H.; Sueyoshi K. and Ohyama T.
Soil Science and Plant Nutrition, 2004, [Reviewed]

Effect of placement of urea and coated urea fertilizers on yield and quality of soybean (Glycine max (L.) Merr.) seeds.
Kaushal T.; Onda M.; Ito S.; Yamazaki A.; Fujikake H.; Ohtake N.; Sueyoshi K.; Takahashi Y. and Ohyama T.
Soil Science and Plant Nutrition, 2004, [Reviewed]

水熱分解技術の有害鳥獣処理への適用　　　　　　　　　　　　　　　
七夕 小百合; 杤本 信彦; 藤原 俊六郎
JATAFFジャーナル, 01 Nov. 2019, [Invited]
Lead

Recycling of nitrogen from shoots to underground parts in hypernodulation mutant lines of soybean by sprit-root experiment.　　　　　　　　　　　　　　　
Ohyama T.; Ueno M.; Ono Y.; Ohtake N.; Sueyoshi K.; Sato T. and Tanabata S.
Bull. Facul. Agric. Niigata Univ., 2018

根圏イメージングによるカドミウム動態のイネ品種間差の解析
鈴井伸郎; 石川覚; 七夕小百合; 石井里美; 井倉将人; 安部匡; 河地有木; 藤巻秀
日本土壌肥料学会講演要旨集, 2013

Leaf growth of Lotus japonicus hypernodulation mutant har1-4.
Tanabata S.; Ohtake N.; Sueyoshi K.; Kawaguchi M. and Ohyama T.
Bull. Facul. Agric. Niigata Univ., 2013

飼料用米生産における豚尿由来液状コンポストの窒素肥効特性．
須藤立; 七夕小百合; 大林康信; 眞部幸子; 井上雅美; 矢萩久嗣
茨城県畜産センター研究報告, 2012

Molecular imaging for plant physiology: Imaging of carbon translocation to sink organs
N. Kawachi; N. Suzui; S. Ishii; S. Ito; N. S. Ishioka; K. Kikuchi; T. Tsukamoto; T. Kusakawa; F. Fujimaki
IEEE Nuclear Science Symposium Conference Record, 2009, [Reviewed]

Allocation of photosynthetic products in hypernodulation mutant of soybean NOD1-3 in the early stage of nodule formation.
Ito S.; Ohtake N.; Sueyoshi K. and Ohyama T.
Bull. Facul. Agric. Niigata Univ., 2006

Comparison of initial growth of hypernodulation soybean mutants, NOD1-3, NOD2-4 and NOD3-7, and their parent cv. Williams.
Ito S.; Ohtake N.; Sueyoshi K. and Ohyama T.
Bull. Facul. Agric. Niigata Univ., 2006

Nitrogen Fertilization Using Drip Fertigation for Cucumber Cultivation Based on Leaf-Count Technique　　　　　　　　　　　　　　　
Tatsuo Sato; Yuki Tashiro; Sayuri Tanabata, Joint work
IntechOpen, Oct. 2023

Amino Acid Metabolism and Transport in Soybean Plants,Chapter 8 "Amino Acid - New Insights and Roles in Plant and Animal"
Takuji Ohyama; Norikuni Ohtake; Kuni Sueyoshi; Yuki Ono; Kotaro Tsutsumi; Manabu Ueno; Sayuri Tanabata; Takashi Sato and Yoshihiko Takahashi, Joint work
Intech Open, Jun. 2017

Role of Nitrogen on Growth and Seed Yield of Soybean and a New Fertilization Technique to Promote Nitrogen Fixation and Seed Yield,Chapter 9 "Amino Acid - New Insights and Roles in Plant and Animal"
Takuji Ohyama; Kaushal Tewari; Shinji Ishikawa; Kazuya Tanaka; Satoshi Kamiyama; Yuki Ono; Soshi Hatano; Norikuni Ohtake; Kuni Sueyoshi; Hideo Hasegawa; Takashi Sato; Sayuri Tanabata; Yoshifumi Nagumo; Yoichi Fujita and Yoshihiko Takahashi, Joint work
Intech Open, Jun. 2017

Advances in Biology and Ecology of Nitrogen Fixation.,Chapter 4 "Autoregulation of nodulation in soybean plants."　　　　　　　　　　　　　　　
Tanabata S. and Ohyama T., Joint work
InTech, 2014

Nitrogen Assimilation in Plants,"Regulation of root nodule formation in leguminous plants."　　　　　　　　　　　　　　　
Ito S.; Fujimaki S.; Kato T.; Ohtake N.; Sueyoshi K. and Ohyama T., Joint work
Research Signpost, 2010

キュウリ先端肥大症の発生に及ぼす植物ホルモンの影響　　　　　　　　　　　　　　　
黄 洁榕; 鷺沼乃々子; 渡部佑月; 小松澤一茶; 李 蕊; 岑 采慧; サティッマンナイタム ジャンジラ; 田代勇樹; 鈴木義人; 七夕小百合; 佐藤達雄
園芸学会令和7年度春季大会, 20 Mar. 2025
20250320, 20250321

Case study on cucumber transportation using modified atmosphere packaging to prevent postharvest deformation, blossom-end enlargement　　　　　　　　　　　　　　　
Yuki Tashiro; Kohei Mochizuki; Erika Uji; Rina Ito; Tran Mi Quyen; Nur Akbar Arofatullah; Agung Dian Kharisma; Sayuri Tanabata; Tatsuo Sato
Postharvest 2024, VII International Symposium
20241111, 20241115

Underlying mechanism of a postharvest deformation, blossom end-enlargement in cucumber fruits　　　　　　　　　　　　　　　
Li Rui; Runewa Atarashi; Agung Dian Kharisma; Nur Akbar Arofatullah; Yuki Tashiro; Junjira Satitmunnaithum; Sayuri Tanabata; Kenji Yamane; Tatsuo Sato
Postharvest 2024, VII International Symposium
20241111, 20241115

サツマイモ育苗における種いもの働きの解明　　　　　　　　　　　　　　　
吉田 穣; 高松 好; サティッマンナイタム ジャンジラ; 浅木直美; 七夕小百合; 佐藤達雄
園芸学会令和6年度秋季大会, 04 Nov. 2024, 園芸学会
20241103, 20241105

キュウリ先端肥大症の発生に対する植物ホルモンの影響　　　　　　　　　　　　　　　
小松澤一茶; 黄 洁榕; 李 蕊; 田代勇樹; 七夕小百合; サティッマンナイタム ジャンジラ; 佐藤達雄
園芸学会令和6年秋季大会, 04 Nov. 2024, 園芸学会
20241103, 20241105

Analysis of the Role of GmNARK in Soybean using Hypernodulation NOD Mutant Lines　　　　　　　　　　　　　　　
Haruka YoshiizumiAyako FurutaniTatsuo SatoGary StaceySayuri Tanabata
2024 IPG Symposium, 21 May 2024
20240521, 20240524

切創が甘藷種いもの萌芽に及ぼす影響　　　　　　　　　　　　　　　
畠山いづみ; 吉田 穣; 高松 好; 棚谷智寿; 岩崎 明; 七夕小百合; 浅木直美; 佐藤達雄
日本作物学会, Sep. 2023
20230914, 20230915

甘藷の空中採苗法の検討　　　　　　　　　　　　　　　
高松 好; 名雪藍那; 畠山いずみ; 吉田 穣; 棚谷智寿; 岩崎 明; 七夕小百合; 浅木直美; 佐藤達雄
日本作物学会, Sep. 2023
20230914, 20230915

Causes of Postharvest Deformation “Blossom-End Enlargement” in Cucumber　　　　　　　　　　　　　　　
Rui Li; Runewa Atarashi; Agung Dian Kharisma; Junjira Satitmunnaithum; Sayuri Tanabata; Tatsuo Sato
American Society for Horticultural Science 2023 Annual Conference, 01 Aug. 2023
20230731, 20230804

ダイズ根粒超着生変異株NOD系統の原因遺伝子と表現型の解析　　　　　　　　　　　　　　　
吉泉春華・古谷綾子・佐藤達雄・七夕小百合
日本土壌肥料学会関東支部大会（茨城大会）, 20 Nov. 2022

ダイズにおける根粒着生形態の違いが生育に及ぼす影響　　　　　　　　　　　　　　　
李 建霖; 佐藤達雄; 七夕小百合
日本土壌肥料学会, Aug. 2018

水熱分解液肥がイネの生育および収量に及ぼす影響　　　　　　　　　　　　　　　
土田直希; 蜷木朋子; 小沢聖; 藤原俊六郎; 七夕小百合
日本土壌肥料学会 関東支部講演会, Nov. 2017

水熱分解液肥がコマツナの生育に及ぼす影響　　　　　　　　　　　　　　　
七夕小百合; 岡部 勝美; 蜷木 朋子; 小沢 聖; 藤原 俊六郎
日本土壌肥料学会, Sep. 2017

キュウリにおける栽培法の違いが窒素・炭素の移行に及ぼす影響　　　　　　　　　　　　　　　
七夕小百合; 浅木 直美; 山口 貴之; 田代 勇樹; 下村 晃一郎; 佐藤 達雄
日本土壌肥料学会, Sep. 2016

野菜残渣水熱分解液肥が作物生育に及ぼす影響（第２報）　　　　　　　　　　　　　　　
七夕小百合; 小沢聖; 藤原俊六郎
日本土壌肥料学会, Sep. 2015

野菜残渣水熱分解液肥が作物生育に及ぼす影響　　　　　　　　　　　　　　　
七夕小百合; 小沢聖; 藤原俊六郎
日本土壌肥料学会, Sep. 2014

ダイズ子実のカドミウム汚染のメカニズム〜ポジトロンイメージング技術×植物栄養学〜　　　　　　　　　　　　　　　
伊藤小百合; 鈴井伸郎; 河地有木; 石岡典子; 藤巻秀
第13回放射線プロセスシンポジウム, Nov. 2009

Characterization of cadmium absorption and transport in soybean plant using radioisotopes ¹⁰⁷Cd and ¹⁰⁹Cd.　　　　　　　　　　　　　　　
Ito S.; Suzui N.; Kawachi N.; Ishioka N.S. and Fujimaki S.
MARCO (Monsoon Asia Agro-Environmental Research Consortium) Symposium, Oct. 2009

ダイズ植物におけるカドミウム吸収および輸送の特性　　　　　　　　　　　　　　　
伊藤小百合; 鈴井伸郎; 河地有木; 石岡典子; 藤巻秀
第4回高崎量子応用研究シンポジウム, Oct. 2009

¹⁰⁷Cdと¹⁰⁹Cdを用いたダイズ子実へのカドミウム移行の生育ステージ毎の解析　　　　　　　　　　　　　　　
伊藤小百合; 鈴井伸郎; 河地有木; 石岡典子; 藤巻秀
日本土壌肥料学会, Sep. 2009

Characterization of cadmium transport in soybean plant using radioisotopes ¹⁰⁷Cd and ¹⁰⁹Cd.　　　　　　　　　　　　　　　
Ito S.; Suzui N.; Kawachi N.; Ishioka N.S. and Fujimaki S.
16th International Plant Nutrition Colloquium, Aug. 2009

Physiological analysis of the autoregulation of nodulation in soybean.　　　　　　　　　　　　　　　
Ito S.; Kato T.; Ohtake N.; Sueyoshi K. and Ohyama T.
The 2nd International symposium on Food Security, Agricultural Development & Environmental Conservation in southeast and east Asia, Sep. 2007

Comparison of leaf growth of hypernodulation soybean mutants, NOD1-3, NOD2-4 and NOD3-7 with their parent cv. Williams.　　　　　　　　　　　　　　　
Ito S.; Ohtake N.; Sueyoshi K. and Ohyama T.
15th international congress on nitrogen fixation & 12th international conference of the African association for biological nitrogen fixation, Jan. 2007

ダイズ品種Williamsと根粒超着生変異株（NOD系統）の地上部初期生育の比較　　　　　　　　　　　　　　　
伊藤小百合; 大竹憲邦; 末吉邦; 大山卓爾
植物微生物研究会, Sep. 2006

ダイズ根粒超着生変異株NOD系統の表現型の比較　　　　　　　　　　　　　　　
伊藤小百合; 大竹憲邦; 末吉邦; 大山卓爾
日本土壌肥料学会, Sep. 2006

Allocation of photosynthetic products in soybean during the early stage of nodule formation.　　　　　　　　　　　　　　　
Ito S.; Kato T.; Ohtake N.; Sueyoshi K. and Ohyama T.
JSPS/NSF Joint seminar: Genetic approach to elucidate molecular mechanism of symbiotic nitrogen fixation, Aug. 2006

ダイズ根粒形成過程における光合成産物の分配　　　　　　　　　　　　　　　
伊藤小百合; 大竹憲邦; 末吉邦; 大山卓爾
植物微生物研究会, Sep. 2005

¹³C標識光合成産物のイネの穂への移動に対する高温ストレスの影響　　　　　　　　　　　　　　　
伊藤小百合; 原武; 木村拓也; 大竹憲邦; 高橋能彦; 佐藤孝; 佐藤敦; 福山利範; 渡邉敏行; 三ツ井敏明; 大山卓爾
日本土壌肥料学会, Sep. 2005

ダイズ根粒形成初期過程における光合成産物の分配　　　　　　　　　　　　　　　
伊藤小百合; 大竹憲邦; 山﨑明彦; 末吉邦; 大山卓爾
日本土壌肥料学会, Sep. 2004

ダイズ根粒形成初期過程における光合成産物の分配　　　　　　　　　　　　　　　
伊藤小百合; 大竹憲邦; 山﨑明彦; 大山卓爾; 末吉邦; 久米民和; 藤巻秀; 石岡典子; 渡辺智; 松橋信平
理工学における同位元素・放射線研究発表会, Jul. 2004

2004, 日本土壌肥料学会