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与玉米混作改善花生铁营养对其根瘤形态结构及豆血红蛋白含量的影响 被引量:33

Effects of Improvement of Iron Nutrition by Mixed Cropping with Maize on Nodule Microstructure and Leghaemoglobin Content of Peanut
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摘要 通过土培方法研究了与玉米混作对花生根瘤形态结构及固氮功能的影响。结果表明 ,玉米与花生混作能够明显地改善花生铁营养、提高根瘤豆血红蛋白的含量。同时 ,单作花生根瘤细胞液泡化程度较高 ,正在发育的根瘤细胞内类菌体数量明显地比混作的花生低。成熟根瘤细胞类菌体周膜外空间 (细胞壁以内、周膜外的空间 )体积变大。说明单作花生固氮酶活性较低的原因是缺铁抑制了豆血红蛋白的合成和改变了根瘤形态结构以及类菌体的超微结构。 The effects of mixed cropping with maize on microstructure and nitrogen-fixing function of peanut nodule were studied in pot experiment. The results showed that mixed cropping with maize remarkably improved iron nutrition of peanut and increased leghaemoglobin content of peanut nodule ( Table 1, Fig.1). At the same time, nodule microstructure and bacterioid ultrastructure were changed, the following results were obtained:(1) Cells in the developing and mature nodules of peanut in monocropping had much larger vacuoles than those in mixed cropping system (Figs.2,4); (2) The number of bacterioid per cell of peanut in monocropping was distinctly decreased (Table 2, Fig.5); (3) Peribacterioid membrane space per cell in the mature nodule of monocropping peanut was bigger than that in mixed cropping with maize (Fig.3). The results showed that iron deficiency of peanut in monocropping had lower production of leghaemoglobin and different microstructure and bacterioid ultrastructure of peanut nodule which led to a lower nitrogenase activity of peanut nodule (Fig.6).
作者 左元梅 刘永秀 张福锁
机构地区 中国农业大学植物营养系
出处 《植物生理与分子生物学学报》 CAS CSCD 2003年第1期33-38,共6页 Journal Of Plant Physiology and Molecular Biology
基金 国家自然科学基金资助项目 (No .30 170 185 )
关键词 花生 铁营养 根瘤 形态结构 豆血红蛋白 固氮酶活性 玉米 混作 类菌体 石灰性土壤 iron nutrition mixed cropping nodule microstructure leghaemoglobin nitrogenase activity
分类号 S565.2 [农业科学—作物学]
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参考文献14

  • 1[1]Applely CA (1984).Leghaemoglobin and Rhizobium respiration. Annu Rev Plant Physiol, 35: 443 - 478
  • 2[2]Bergersen FJ, Goodchild DJ(1973). Cellular location of leghaemoglobin in soybean root nodules. Aust J Biol Sci, 26: 741-756
  • 3[3]Dakora DF(1991). Effects of pO2 on the formation and status of leghaemoglobin. Plant Physiol, 95:723 -730
  • 4[4]Dakora DF(1995). A functional relationship between leghaemoglobin and nitrogenase based on novel measurements of the proteins in legume root nodules. Ann Bot, 15: 49-54
  • 5[5]O'Hara GW, Dilworth MJ, Boonkerd N(1988). Iron-deficiency specifically limits nodule development in peanut inoculated with Bradyrhizobium sp. New Phytol, 108:51-57
  • 6[6]O'Hara GW(1988). Mineral constraints to nitrogen fixation. Plant Soil, 108: 93-110
  • 7[7]Rai R, Prasad V, Choudhury SK (1984). Iron nutrition and symbiotic N2 fixation of lentil (Lens culinaris) genotypes in calcareous soil. J Plant Nutrition, 7:399-405
  • 8[8]Riley BT, Dilworth MJ (1985). Cobalt requirement for nodule development and function in Lupinus angustifolius L. New Phytol, 100:347-359
  • 9[9]Roessler PG, Nadler KD (1982). Effects of iron deficiency on heme biosynthesis in Rhizobium japonicum. J Bacteriol, 149:1021-1026
  • 10[10]Sinclair TR,Serraj R (1995). Legume nitrogen fixation and drought. Nature, 378 (23): 344-347

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植物生理与分子生物学学报
2003年 第1期

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