The Korean Journal of Ecology

The Ecological Society of Korea (한국생태학회)
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Effects of Nitrogen Application on the Patterns of Amino Acids, Nitrogen Contents and Growth Response of Four Legume Plants under Saline Conditions

염분 환경하에서 4종 콩과식물의 생장, 아미노산 및 질소함량에 미치는 질소원의 영향

  • Published : 2003.06.01
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Abstract

Four legume plants showed better growth by the external nitrogen supply rather than the symbiotic nitrogen fixation only under salt additions. In case of Glycine max and Phaseolus angularis, total nitrogen contents decreased by high salinity level but their amino acid levels significantly increased with the increase of salt treatments and indicated high soluble-/insoluble-N ratios. Cassia tora and Albizzia julibrissin contained less amino acids than G. max and P. angularis but total N (esp. insoluble N fraction) increased with higher salt levels. Asparagine occurred as a main amino acid especially in G. max and P. angularis and can be seen as potential N-storage form in these plants. It might be play an important role for the osmoregulation mechanism under the saline condition. Meanwhile, to investigate what kinds of nitrogen sources are effective for overcoming salt stress on soybean plants, various N forms and concentrations (NH₄NO₃-N, NO₃-N, NH₄NO₃-N; 2.5 and 5 mM) were additionally supplied to the salt gradient medium. Soybean plants treated with NH₄NO₃-N showed the best growth up to 40 mM NaCl and NO₃- fed plants indicated good growth even at 80 mM NaCl treatments. Contrary to NH₄NO₃- and NO₃- fed plants, NH₄/sup +/- fed plants showed remarkable growth reduction and died by 40 and 80 mM NaCl treatments after the first harvest (15th day). Consequently, these results suggest that salt excluding and resistant capacities of soybean plants under NaCl treatments are increased in order of NH₄ - N, control, NO₃- N and NH₄NO₃- N depending on N concentration except NH₄- N treatments.

콩과식물의 염분 내성에 대한 질소원의 영향을 규명하기 위하여 4종 콩과식물을 선택하여 100 mM까지의 NaCl을 처리하였다. 염-민감성 종으로 알려진 대두와 팥은 염분 농도가 증가함에 따라 총 질소 함량이 점차 감소하는 반면, 아미노산 함량은 현저히 증가(100 mM NaCl 처리된 대두 무질소구의 경우 대조구의 4.7배)하여 높은 가용성/불용성 질소 비를 보였다. 대조적으로 염분 내성을 보이는 긴강남차와 자귀나무는 아미노산을 거의 함유하지 않았으며, 염 구배에 따라 총 질소 함량(특히 불용성 질소)이 점차 증가하는 양상을 보였다. 대두와 팥은 아미노산 중 asparagine (Asn)을 다량으로 함유하였으며, Asn은 이들 식물의 대표적인 질소의 수송 및 저장형태로서 염분 환경하에서 이들 식물의 세포질 내 삼투조절에 관여하는 것으로 생각된다. 염 환경에서 대두의 생장에 대한 질소원 및 농도의 영향은 5 mM NH₄NO₃-N 처리구에서 가장 높은 건물함량(10mM NaCl 처리구의 지상부건물함량의 경우 대조구의 약 1.5배)을 보였고, NH₄-N을 공급한 식물의 경우 질소를 공급하지 않은 대조구보다 생장이 저해되었으며, 처리 15일 이후 40과 80 mM NaCl 처리구에서 모두 고사하였다. 따라서 대두의 생장은 NH₄-N, 대조구, NO₃-N, NH₄NO₃-N의 순으로 질소공급량이 증가할수록 염에 대한 저항성이 증가하는 것으로 나타났다.

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