四翅滨藜和多枝柽柳对土壤干旱的响应差异
收稿日期: 2023-05-15
修回日期: 2023-07-12
网络出版日期: 2023-12-18
基金资助
新疆生产建设兵团重大科技项目(2021AB022);艾西曼荒漠化治理植物选择及适应性研究项目(1123017)
Differences in the response to soil drought in Atriplex canescens and Tamarix ramosissima
Received date: 2023-05-15
Revised date: 2023-07-12
Online published: 2023-12-18
在干旱区防护林建设中,选择抗逆性和适应力强的植物树种是关键。通过模拟不同干旱梯度的盆栽控水试验来比较塔里木盆地引种植物四翅滨藜和乡土植物多枝柽柳对干旱胁迫生态适应性差异。结果表明:(1) 随着干旱程度增加,四翅滨藜和多枝柽柳叶片含水量均逐渐降低,保水力、脯氨酸含量、相对电导率逐渐增大。四翅滨藜和多枝柽柳的可溶性糖含量、丙二醛含量分别在轻度、重度干旱下达最大值,多枝柽柳的增幅更大。(2) 四翅滨藜和多枝柽柳POD活性逐渐增大,重度干旱下,多枝柽柳较对照增加的百分比约为四翅滨藜的3倍;在中度干旱下SOD活性最大,多枝柽柳较对照增加的百分比约为四翅滨藜的5倍。多枝柽柳2种酶活性变化均大于四翅滨藜。(3) 四翅滨藜和多枝柽柳叶绿素含量均为: 轻度干旱>对照>中度干旱>重度干旱,多枝柽柳的净光合速率、蒸腾速率、气孔导度和胞间二氧化碳浓度均逐渐降低,轻度干旱对四翅滨藜叶绿素和光合能力有略微促进作用。(4) 相关性和主成分分析结果显示,干旱胁迫下多枝柽柳各性状间的联系更紧密,四翅滨藜不易改变性状和性状之间的联系,相对保守。四翅滨藜受到干旱胁迫的影响较小,其干旱适应性略强于多枝柽柳。
胡焕琼 , 李利 , 于军 , 梁海连 , 吕瑞恒 . 四翅滨藜和多枝柽柳对土壤干旱的响应差异[J]. 干旱区研究, 2023 , 40(12) : 2007 -2015 . DOI: 10.13866/j.azr.2023.12.13
To construct shelter forests in arid areas, selecting plant species with strong stress tolerance and adaptability is key. By simulating a pot water control experiment with different drought gradients, the ecological adaptability of the introduced plant Atriplex canescens and the native plant Tamarix ramosissima willow to drought stress were compared. The results showed that (1) With an increase in drought degree, the water content in the A. canescens and T. ramosissima leaves reduced gradually, and the water retention capacity, proline content, and relative conductivity gradually increased. The soluble sugar and malondialdehyde contents of A. canescens and T. ramosissima were the maximum in mild and severe drought, respectively, and the increase rate was greater in T. ramosissima. (2) The POD activity of A. canescens and T. ramosissima increased gradually, and under severe drought, the percentage increase of T. ramosissima compared with the control was approximatelythree times that of A. canescens; SOD activity was greatest under moderate drought, and the percentage increase in T. ramosissima compared with the control was approximatelyfive times that of A. canescens. The changes in the activity of both enzymes of T. ramosissima were greater than those of A. canescens. (3) The chlorophyll content of A. canescens and T. ramosissima were mildly dry > control > moderate drought > severe drought, the net photosynthetic rate, transpiration rate, stomatal conductance, and intercellular carbon dioxide concentration of T. ramosissima gradually decreased, and mild drought slightly promoted chlorophyll and photosynthetic capacity of A. canescens. (4) The correlation and principal component analysis results indicated that the relationship between the T. ramosissima traits was closer under drought stress, and the relationship between traits and traits was difficult to change in A. canescens, which was relatively conservative. Conclusion: A. canescens is less affected by drought stress, and its drought adaptability is slightly stronger than that of T. ramosissima.
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