Korean Journal of Soil Science and Fertilizer (한국토양비료학회지)

Korean Society of Soil Science and Fertilizer (한국토양비료학회)
권호 표지

Changes in the Nitrate Assimilation and Ascorbic Acid Content of Spinach Plants Treatmented with Nutrient Solutions Containing High Nitrogen and Low Potassium

고질소 및 저 칼륨 양액처리시 시금치내의 비타민C및 질소 대사의 변화

  • Received : 2009.06.25
  • Accepted : 2009.07.30
  • Published : 2009.08.28
Download PDF
⟨ Previous Next ⟩

Abstract

This study was conducted to determine the physiological differences betweenhealthy and wilted plants with respect to nitrate assimilation and ascorbic acid content. Wilting was artificially induced in spinach plants by treating the seeds with nutrient solution containing high nitrogen and low potassium. The plants were cultured in different plots 4 types of media: 1N-1P-1K (control), 6N-1P-0K (0K), 6N-1P-0.5K (0.5K), and 6N-1P-2K (2K). The rate of wilting among the plants was as follows: control, 0%; 2K, 10%; 0.5K, 40%; and 0K, 70%. This shows that under high nitrogen conditions, the lower the amount of potassium provided, higher was the rate of wilting. There were no differences in plant growth among the plants treated with different levels of potassium under high nitrogen conditions.The nitrate content in both the leaves and the roots was higher in plants grown under high nitrogen media than those in the control. Furthermore, the nitrate level decreased with increasing potassium concentration. The ascorbic acid content of spinach under high nitrogen conditions was lower than those of the control.

이 연구의 목적은 건강한 작물과 시들은 식물의 질소대사와 아스코리빈산 함량의 차이를 비교하는것에 있다. 시듬은 인공적으로 유도되었으며, 그방은 질소과다 시비 및 저칼륨 시비에 의한 것으로4개의 처리구를 두었다. 1N-1P-1K (control), 6N-1P-0K (0K), 6N-1P-0.5K (0.5K), and 6N-1P-2K (2K). 시듬 정도는 control, 0%; 2K, 10%; 0.5K, 40%; and 0K, 70%. 식물 생장에는 고질소 저 칼륨 처리구에서는 그리 큰 차이가 없었으며 질산태질소의 함량은 control 구와 비교하여 고 질소 처리구가 높았으며, 아스코리빈 산 함량은 고질소 처리구가 control구에 비하여 낮았음을 확인 할수 있었다.

Keywords

References

  1. Agro-Environment, R. 2004. Agro-Environment Research. Department of Agro-Environment, National Institute of Agricultural Science and Technology
  2. Cushnaha, A., j.S. Bailey, and F.J. Gordon. 1995. Some effects of sodium application on the yield and chemical composition of pasture grass under differing conditions of potassium and moisture supply. Plant and Soil 176:117-127 https://doi.org/10.1007/BF00017682
  3. Lorenz, O.A., and B.L. Weir. 1974. Nitrate accumulation in vegetables. Environmental Quality and Food Supply:93-103
  4. Maozafar, A. 1993. Nitrogen fertilizers and the amount of vitamins in plants : A review. Journal of Plant Nutrition 16 (12):2479-2506 https://doi.org/10.1080/01904169309364698
  5. Maynard, D.N., A.V. Barker, P.L. Minotti, and N.H. Peck. 1976.Nitrate accumulation in vegetables. Advances in Agronomy 28:71-118 https://doi.org/10.1016/S0065-2113(08)60553-2
  6. Park, Y.H., S.H. Park, and J.H. Park. 2006a. Continuous-Flow analysis for determination of nitrate in plant by using hydrazinecopper method. Korean Journal of Soil Science and Fertilizer 39(4):204-208
  7. Park, Y.H., S.H. Park, J.H. Park, J.Y. Lee, B.C. Jang, and K.S. Lee.2006b. Changes of ascorbic acid and nitrate content in lettuce by unbalanced nutrient solution. The Korea Society of Crop Science 51 (1):107-111
  8. Robinson, J.M. 1984. Photosynthetic carbon metabolism in leaves and isolated chloroplasts from spinach plants grown under short and intermediate photosynthetic periods. Plant Physiology 75:397-409 https://doi.org/10.1104/pp.75.2.397
  9. Scholl, R.L., J.E. Harper, and R.H. Hageman. 1974. Improvements of the nitrite color development in assays of nitrate reductase by phenazine methasulfate and zinc acetate. Plant Physiology 53:825-828 https://doi.org/10.1104/pp.53.6.825
  10. Walinga, I., W.V. Vark, V.J.G. Houba, and J.J. Vand der lee. 1989. Soil and Plant Analysis. Wageningen Agricultural University,Wagenningen, the Netherlands:264