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Effects of Hypoxia on 13NH4+ Fluxes in Rice Roots. Kinetics and compartmental analysis Kinetics and Compartmental Analysis.缺氧对水稻根系13NH4+通量的影响。动力学与区室分析 动力学与区室分析
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Differential expression of three members of the AMT1 gene family encoding putative high-affinity NH4+ transporters in roots of Oryza sativa subspecies indica.编码假定的高亲和力铵转运蛋白的AMT1基因家族的三个成员在籼稻根中的差异表达。
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Kinetics of NH (4) (+) uptake by the arbuscular mycorrhizal fungus Rhizophagus irregularis.丛枝菌根真菌粗糙球囊霉对铵(NH4+)吸收的动力学。
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Tipping the plant-microbe competition for nitrogen in agricultural soils.改变农业土壤中植物与微生物对氮的竞争态势。
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Identification of candidate genes and residues for improving nitrogen use efficiency in the N-sensitive medicinal plant Panax notoginseng.鉴定候选基因和残基,以提高对氮敏感的药用植物三七的氮利用效率。
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CIPK15-mediated inhibition of NH transport protects from submergence.CIPK15介导的铵转运抑制作用可保护植物免受淹水胁迫。
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Nuclear translocation of OsMADS25 facilitated by OsNAR2.1 in reponse to nitrate signals promotes rice root growth by targeting OsMADS27 and OsARF7.硝酸盐信号诱导 OsNAR2.1 介导 OsMADS25 入核,靶向 OsMADS27 和 OsARF7 促进水稻根生长。
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In vivo visualization of nitrate dynamics using a genetically encoded fluorescent biosensor.利用基因编码荧光生物传感器在体可视化硝酸盐动力学。
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High Levels of Zinc Affect Nitrogen and Phosphorus Transformation in Rice Rhizosphere Soil by Modifying Microbial Communities.高锌水平通过改变微生物群落影响水稻根际土壤中氮和磷的转化。
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Does energy cost constitute the primary cause of ammonium toxicity in plants?能量成本是否构成植物铵毒性的主要原因?
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本文引用的文献
1
Studies of the Uptake of Nitrate in Barley: I. Kinetics of NO(3) Influx.大麦硝酸盐吸收的研究:I. 硝酸盐流入的动力学。
Plant Physiol. 1990 Aug;93(4):1426-32. doi: 10.1104/pp.93.4.1426.
2
Nitrogen Utilization in Lemna: II. Studies of Nitrate Uptake Using NO(3).氮在浮萍中的利用:二、利用硝酸盐进行的硝酸根吸收研究。
Plant Physiol. 1987 Nov;85(3):860-4. doi: 10.1104/pp.85.3.860.
3
Potassium transport in corn roots : I. Resolution of kinetics into a saturable and linear component.玉米根中的钾转运:I. 将动力学分解为饱和成分和线性成分
Plant Physiol. 1982 Dec;70(6):1723-31. doi: 10.1104/pp.70.6.1723.
4
Effect of exogenous and endogenous nitrate concentration on nitrate utilization by dwarf bean.外源和内源性硝酸盐浓度对矮生菜豆硝酸盐利用的影响。
Plant Physiol. 1982 Sep;70(3):754-9. doi: 10.1104/pp.70.3.754.
5
Relationships between Root Temperature and the Transport of Ammonium and Nitrate Ions by Italian and Perennial Ryegrass (Lolium multiflorum and Lolium perenne).意大利黑麦草和多年生黑麦草(多花黑麦草和黑麦草)的根温与铵根和硝酸根离子运输的关系。
Plant Physiol. 1979 Oct;64(4):557-61. doi: 10.1104/pp.64.4.557.
6
Comparison of the uptake of nitrate and ammonium by rice seedlings: influences of light, temperature, oxygen concentration, exogenous sucrose, and metabolic inhibitors.水稻幼苗对硝酸盐和铵盐吸收的比较:光照、温度、氧浓度、外源蔗糖和代谢抑制剂的影响。
Plant Physiol. 1978 Oct;62(4):665-9. doi: 10.1104/pp.62.4.665.
7
Regulation of potassium absorption in barley roots: an allosteric model.大麦根系钾吸收的调节:变构模型。
Plant Physiol. 1976 Jul;58(1):33-7. doi: 10.1104/pp.58.1.33.
8
Ammonium Uptake by Rice Roots (I. Fluxes and Subcellular Distribution of 13NH4+).水稻根系对铵的吸收(I. 13NH4+的通量和亚细胞分布)
Plant Physiol. 1993 Dec;103(4):1249-1258. doi: 10.1104/pp.103.4.1249.
9
Feedback Regulation of Nitrate Influx in Barley Roots by Nitrate, Nitrite, and Ammonium.硝酸盐、亚硝酸盐和铵对大麦根中硝酸盐流入的反馈调节
Plant Physiol. 1993 Aug;102(4):1279-1286. doi: 10.1104/pp.102.4.1279.
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Utilization of ammonium as a nitrogen source: effects of ambient acidity on growth and nitrogen accumulation by soybean.以铵作为氮源的利用:环境酸度对大豆生长和氮积累的影响。
Plant Physiol. 1986;82(1):54-60. doi: 10.1104/pp.82.1.54.
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