Nitrogen plays a major role in leaves when source-sink relations change: C and N metabolism in Lolium perenne growing under free air CO2 enrichment

Australian Journal of Plant Physiology Pub Date : 2000-09-22 DOI:10.1071/PP99151

H. Isopp, M. Frehner, J. Almeida, H. Blum, M. Daepp, U. Hartwig, A. Lüscher, D. Suter, J. Nösberger

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引用次数: 40

Abstract

Swards of Lolium perenne L. were grown in the field in a long-term free air CO2 enrichment (FACE) facility. The CO2 treatment was combined with two levels of N fertilization and regular defoliation, which resulted in plants with a wide range of source-sink relations. C and N metabolism were investigated to assess the role of carbohydrate and nitrogenous compounds in leaves in indicating source-sink relations. Sucrose exhibited the largest changes in contents during the day-night cycle; therefore, it was identified as the main short-term storage compound for night-time export. Fructan accumulation indicated the degree of surplus C supply in the source compared to C use in sinks. Nitrate content depended mainly on N fertilization, and was reduced under elevated pCO2. Nitrate appeared to indicate a current surplus of available N relative to the need for growth. Amino acid content responded strongly to N fertilization but decreased only slightly under elevated pCO2. Protein content, however, decreased significantly under elevated pCO2. The patterns of diurnal changes of C or N compounds did not differ between CO2 treatments. Down-regulation of photosynthesis appeared to occur when plants were extremely N-limited as under elevated pCO2, low N and at a late regrowth stage.

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当源库关系发生变化时，氮在叶片中起主要作用:在自由空气CO2富集条件下生长的黑麦草C、N代谢

在一个长期的自由空气CO2富集(FACE)设施中，田间种植了多年生黑麦草(Lolium perenne L.)。CO2处理与两个水平的氮肥和定期落叶相结合，使植物具有广泛的源库关系。研究了碳氮代谢，以评估叶片中碳水化合物和氮化合物在指示源库关系中的作用。蔗糖在昼夜循环中含量变化最大;因此，它被确定为夜间出口的主要短期储存化合物。果聚糖积累表明了源碳供应过剩的程度与汇碳利用的程度。硝态氮含量主要依赖于施氮，在pCO2升高的情况下，硝态氮含量降低。硝酸盐似乎表明，相对于生长的需要，目前有效氮的过剩。氨基酸含量对施氮反应强烈，但在二氧化碳分压升高时仅略有下降。然而，在pCO2升高的情况下，蛋白质含量显著降低。不同CO2处理间碳、氮的日变化规律无显著差异。在co2浓度升高、低氮和再生后期等极限氮条件下，光合作用出现下调。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Australian Journal of Plant Physiology

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