| 1. |
伊藤岳洋, 張柳, 大津(大鎌)直子, 丸山明子, 硫黄欠乏に対する植物の応答. 〜適応のための内的動態〜, 化学と生物, 2022.10. |
| 2. |
丸山 明子, 硫酸イオンの輸送機構, 日本土壌肥料学雑誌, 2021.04. |
| 3. |
Y. Nakai and A. Maruyama-Nakashita, Biosynthesis of Sulfur-Containing Small Biomolecules in Plants, Current Opinion in Plant Biology, doi.org/10.3390/ijms21103470, 2020.05. |
| 4. |
A. Maruyama-Nakashita, Metabolic changes sustain the plant life in low-sulfur environments, Current Opinion in Plant Biology, http://dx.doi.org/10.1016/j.pbi.2017.06.015, 2017.11, Plants assimilate inorganic sulfate into various organic sulfur (S) compounds, which contributes to the global sulfur cycle in the environment as well as the nutritional supply of this essential element to animals. Plants, to sustain their lives, adapt the flow of their S metabolism to respond to external S status by activating S assimilation and catabolism of stored S compounds, and by repressing the synthesis of secondary S metabolites like glucosinolates. The molecular mechanism of this response has been gradually revealed, including the discovery of several regulatory proteins and enzymes involved in S deficiency responses. Recent progress in this research area and the remaining issues are reviewed here.. |
| 5. |
丸山 明子, 吉本尚子, 植物の硫酸イオン吸収の制御機構, 硫酸と工業, 2016.08. |
| 6. |
丸山 明子, 斉藤和季, 吉本尚子, 植物の硫酸イオン吸収と同化, 硫酸と工業, 2016.07. |
| 7. |
丸山 明子, 植物の維管束を介した硫酸イオン輸送 -SULTR2;1の働きを中心に-, RADIOISOTOPES 64: 609-612., 査読あり, 2015.09. |
| 8. |
丸山 明子, 植物細胞内の硫酸イオン輸送, RADIOISOTOPES 64: 549-551. , 査読あり, 2015.08. |
| 9. |
A. Maruyama-Nakashita, Transcriptional regulation of genes involved in sulfur assimilation in plants: Understanding from the analysis of high-affinity sulfate transporters., Plant Biotech. 25, 323-328., 2008.06. |
| 10. |
丸山明子、高橋秀樹, 植物の硫酸イオントランスポーターとその制御, 植物の生長調節 41: 46-55., 2006.02. |
| 11. |
高橋秀樹、丸山明子, 硫黄代謝制御因子SLIM1の発見, バイオサイエンスとインダストリー 64: 34-36., 2006.10. |
