土壤Pb含量对杨树幼苗生理生长影响的综合因素分析

doi:10.11707/j.1001-7488.20151117

摘要/Abstract

摘要： [目的]研究杨树幼苗生理生长变化与土壤Pb含量的关系及对Pb吸收分布的特征,为利用杨树修复环境提供依据。[方法]选取加拿大杨树幼苗为试材,按土壤中添加Pb的含量不同分成5个组进行盆栽,测量叶绿素含量、净光合速率、POD、SOD、CAT、丙二醛(MDA)、生物量、株高、Pb含量9个生理生长指标,依据杨树幼苗生理生长指标变化特点,将5个组分成无污染、轻度污染和重度污染3个大类别,采用方差分析法、综合相关分析法、矢量综合相关分析法和判别分析法进行分析。[结果] 1)随着土壤Pb含量的升高,杨树幼苗的生长指标值(生物量和株高)和正生理指标值(叶绿素含量、净光合速率P_n)随之降低,负生理指标值(SOD、POD、CAT和MDA)则随之升高。2)杨树幼苗的生长指标值与正生理指标叶绿素含量、净光合速率P_n值在土壤Pb浓度<1045 mg·kg^-1时,各组间基本无显著差异, ≥1045 mg·kg^-1时,各组间存在显著差异。负生理指标(SOD、POD、CAT和MDA)正好相反。3)杨树幼苗的生长指标组(生物量、株高)、正生理指标组(叶绿素含量、净光合速率P_n)、负生理指标组(SOD、POD、CAT和MDA)分别在无污染、轻度污染和重度污染3大类别的正确判别率都很高,说明土壤Pb污染含量划分的正确性,能很好地反映杨树幼苗生长生理变化特征。4)杨树幼苗的生长指标组(生物量和株高)和正生理指标组(叶绿素含量、净光合速率P_n)无论是直接相关还是综合相关,都存在显著、极显著的正相关。杨树幼苗的生长指标组(生物量、株高)和负生理指标组(SOD、POD、CAT和MDA)无论是直接相关还是综合相关,都呈显著、极显著负相关。正生理指标和负生理指标间呈显著负相关。5)杨树幼苗根、茎、叶中富集的Pb浓度随土壤Pb含量升高而升高,但根是最主要的吸收部位。除无污染情况外,在土壤Pb含量为1045 mg·kg^-1时,杨树幼苗根、茎、叶以及幼苗整株的Pb转移系数最高。[结论]土壤Pb含量为1045 mg·kg^-1具有重要的临界值意义。当土壤Pb含量<1045 mg·kg^-1时,杨树幼苗可通过自身的抗胁迫响应能力基本保持正常生长,并保持较高的转移系数;当土壤Pb含量 ≥1045 mg·kg^-1,杨树幼苗会受到严重胁迫,不能很好生长,同时也不能保持较高的转移系数、最有效地改良土壤。方差分析、综合相关分析,判别分析等多种统计方法的有机结合,能从不同方面,不同层次很好地揭示杨树幼苗生长与生理之间内在的复杂关系,以及生长、生理与土壤Pb含量之间的复杂关系。

关键词: Pb, 杨树幼苗, 生理指标, 综合因素分析

Abstract: [Objective] In this paper, we aimed at studying the impact of soil Pb on the physiological indicators and growth of Populus seedlings. [Method] Potting seedlings of Populus canadensis were subjected to five different concentrations of the soil lead, and the physiological indicators, including the content of chlorophyll、the net photosynthetic rate (P_n), the activity of CAT, POD, SOD, the content of MDA, the height and biomass of plants and the content of Pb, were measured. According to the variation of physiological indicators, the five groups were classified into three categories, no pollution, light pollution and severe pollution. Data were analyzed with the methods of ANOVA, comprehensive correlation analysis, vector comprehensive and correlation analysis as well as discriminant analysis. [Result] Firstly, the growth indicators (biomass and plant height) and positive physiological indicator (chlorophyll content, the net photosynthetic rate (P_n)) of the seedlings were decreased as the concentration of Pb was increased, but negative physiological indicators (SOD, POD, CAT and MDA) were subsequently increased. Secondly, there were no significant differences in growth and positive physiological indicators among the five groups when the concentrations of Pb were less than 1045 mg·kg^-1, however, when the concentrations of Pb were more than 1045 mg·kg^-1, the differences were significant. However, the negative physiological indicators (SOD, POD, CAT and MDA) were opposite. Thirdly, The correct discrimination rate of growth index, positive and negative physiological indicators in no pollution, light pollution and severe pollution groups was very high, indicating that the partition of Pb concentration was correct, and can well reflect the variation of growth and physiological indicators. Fourthly, the growth (biomass and plant height) showed significantly positive correlation with the positive physiological indicators (chlorophyll content, the net photosynthetic rate (P_n)), but exhibited significantly negative correlation with negative physiological indicators (SOD, POD, CAT and MDA). Fifthly, the concentrations of Pb in the root, stem and leaf of seedlings were all increased as the concentration of the soil Pb increased, especially in the root. The transfer coefficients of Pb in roots, stems, leaves and whole plants were highest when the concentration of the soil Pb was 1045 mg·kg^-1. [Conclusion] The concentration of 1045 mg·kg^-1 Pb in soil was a key critical value, below which Populus can maintain normal growth and keep a higher transfer coefficient with the ability of stress resistance. But when the concentration of Pb in soil is more than 1045 mg·kg^-1, growth of seedlings was inhibited and the transfer coefficient decreased sharply. Combined methods of ANOVA, correlation analysis, and discriminant analysis, applied in this studies, can reveal the comprehensive correlation between seedling growth and concentration of soil Pb.

Key words: Pb, seedling of Populus canadensis, physiological indicator, comprehensive factor analysis

中图分类号:

S718.45

杨建伟, 杜瑞卿, 沙文沛, 余明玉, 高宛莉, 张征田. 土壤Pb含量对杨树幼苗生理生长影响的综合因素分析[J]. 林业科学, 2015, 51(11): 128-136.

Yang Jianwei, Du Ruiqing, Sha Wenpei, Yu Mingyu, Gao Wanli, Zhang Zhengtian. Comprehensive Factor Analysis about the Impact of Soil Pb Content on Seedling Growth of Populus canadensis[J]. Scientia Silvae Sinicae, 2015, 51(11): 128-136.

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