Chenxi Zhang, Haibo Li, Fan Mo, Mingshuai Wang, Yaran Bai, Haotian Ma, Bingqian Gao, Rui Wang
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引用次数: 0
摘要
本研究旨在说明不同重金属胁迫水平下高度适应重金属的植物根瘤层微生态特征的时空变化规律,揭示根瘤层养分循环和抗逆性增强的机理。研究了不同浓度镉处理下白三叶(Trifolium repens L.)根瘤菌圈微生态的动态变化。通过原位酶图法原位和显微研究了土壤酶活性的空间变化,并建立了酶活性的空间分布模型。结果表明,在 40 天的胁迫下,根瘤生态系统保持相对稳定,pH 值在 7.13 至 7.26 之间,有机质含量在 14.83 至 18.09 g kg- 1 之间。此外,pH 值和土壤有机质(SOM)也是影响根瘤菌圈中镉活化的重要生态因子。根据土壤酶谱分析,磷酸酶和 N-乙酰-氨基葡萄糖苷酶热点均对根部有影响,在 10 mg kg- 1 Cd 处理时,热点面积最大,分别为 21.51% 和 10.19%。此外,在 5 mg kg- 1 Cd 处理条件下,两种酶的活性最大,根圈扩展距离分别达到 1.82 厘米和 1.59 厘米。这项研究揭示了白三叶潜在的根圈调节机制。研究强调,在 5-10 mg kg- 1 Cd 胁迫下,根圈中 Cd 的生物利用率增加,与 N 和 P 循环相关的酶的活性受到刺激,因此 Cd 造成的土壤 N 损失可在根圈中得到补偿。
Rhizosphere Ecological Characteristics of Trifolium repens L. under Cadmium Stress: with Focus on the Spatial Distribution Pattern of Enzyme Activity
This study aims to illustrate the temporal and spatial patterns of rhizosphere microecological characteristics of plants highly adapted to heavy metals under different levels of heavy metal stress, to reveal the rhizosphere nutrient cycling and the mechanism of enhanced stress tolerance. The dynamic changes of rhizosphere microecology of Trifolium repens L. (white clover) were studied under different concentrations of Cd treatment. The spatial variation of soil enzyme activities was investigated in situ and microscopically by in situ zymography and the spatial distribution models of enzyme activities were developed. The results showed that the rhizosphere ecosystem remained relatively stable under 40 days of stress, with pH ranging from 7.13 to 7.26 and organic matter contents ranging from 14.83 to 18.09 g kg− 1. In addition, pH and soil organic matter (SOM) were important ecological factors affecting Cd activation in the rhizosphere. Based on soil zymography analysis, both phosphatase and N-acetyl-glucosaminidase hotspots had root effects, and a maximum hotspot area of 21.51 and 10.19% at 10 mg kg− 1 Cd treatment, respectively. Besides, the maximum activities of both enzymes were observed at 5 mg kg− 1 Cd treatment and the rhizosphere extension distance up to 1.82 and 1.59 cm. This study reveals the potential rhizosphere regulatory mechanism of white clover. It was emphasized that the Cd bioavailability was increased in the rhizosphere, the activities of enzymes related to N and P cycling were stimulated under 5–10 mg kg− 1 Cd stress, and thus soil N loss due to Cd could be compensated in the rhizosphere.
期刊介绍:
The Journal of Soil Science and Plant Nutrition is an international, peer reviewed journal devoted to publishing original research findings in the areas of soil science, plant nutrition, agriculture and environmental science.
Soil sciences submissions may cover physics, chemistry, biology, microbiology, mineralogy, ecology, pedology, soil classification and amelioration.
Plant nutrition and agriculture submissions may include plant production, physiology and metabolism of plants, plant ecology, diversity and sustainability of agricultural systems, organic and inorganic fertilization in relation to their impact on yields, quality of plants and ecological systems, and agroecosystems studies.
Submissions covering soil degradation, environmental pollution, nature conservation, and environmental protection are also welcome.
The journal considers for publication original research articles, technical notes, short communication, and reviews (both voluntary and by invitation), and letters to the editor.