Ming Ding
Nanjing Agricultural University
9 Papers
1 Citations
Ming Ding is an academic researcher from Nanjing Agricultural University. The author has contributed to research in topics: Transcriptome & Chemistry. The author has an hindex of 6, co-authored 9 publications.
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Papers
Plasma membrane H+-ATPase overexpression increases rice yield via simultaneous enhancement of nutrient uptake and photosynthesis
Maoxing Zhang,Yin Wang,Xi Chen,Feiyun Xu,Ming Ding,Wenxiu Ye,Wenxiu Ye,Yuya Kawai,Yosuke Toda,Yosuke Toda,Yuki Hayashi,Takamasa Suzuki,Houqing Zeng,Liang Xiao,Xin Xiao,Jin Xu,Shiwei Guo,Feng Yan,Qirong Shen,Guohua Xu,Toshinori Kinoshita,Yiyong Zhu +21 more
TL;DR: In this article, a single rice gene, Oryza sativa plasma membrane (PM) H+-ATPase 1 (OSA1), facilitates ammonium absorption and assimilation in roots and enhanced light-induced stomatal opening with higher photosynthesis rate in leaves.
Overexpression of rice aquaporin OsPIP1;2 improves yield by enhancing mesophyll CO2 conductance and phloem sucrose transport
Feiyun Xu,Feiyun Xu,Ke Wang,Wei Yuan,Weifeng Xu,Shuang Liu,Herbert J. Kronzucker,Guanglei Chen,Rui Miao,Maoxing Zhang,Ming Ding,Liang Xiao,Lei Kai,Jianhua Zhang,Yiyong Zhu +14 more
TL;DR: OsPIP1;2 overexpression enhances rice growth and grain yield by facilitating leaf CO2 diffusion, which increases the net CO2 assimilation rate and phloem sucrose transport.
Potassium alleviates ammonium toxicity in rice by reducing its uptake through activation of plasma membrane H+-ATPase to enhance proton extrusion.
Lingyin Weng,Maoxing Zhang,Ke Wang,Guanglei Chen,Ming Ding,Wei Yuan,Yiyong Zhu,Weifeng Xu,Feiyun Xu +8 more
TL;DR: Results indicate that K+ can alleviate NH4+ toxicity, possibly by activating PM H+-ATPase to extrude more H+ and inhibitNH4+ uptake by root and enhance the H+ extrusion rate by the roots.
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Transcriptome profiles of soybean leaves and roots in response to zinc deficiency.
TL;DR: The transcriptomic profilings of soybean leaves and roots in response to Zn deficiency through Illumina's high-throughput RNA sequencing are analyzed to understand the molecular basis of Zn-deficiency response in the plants and to provide comprehensive insights into the soybean response toZn deficiency.
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Integrated analyses of miRNAome and transcriptome reveal zinc deficiency responses in rice seedlings
TL;DR: Insight is provided into miRNA-mediated regulatory pathways in Zn deficiency response, and candidate genes for genetic improvement ofZn deficiency tolerance in rice seedlings are provided.