囊果碱蓬离子含量及分布特点

干旱区地理 ›› 2017, Vol. 40 ›› Issue (2): 365-372.

囊果碱蓬离子含量及分布特点

李艳红¹, 涂锦娜¹, 张道远², 王雷², 田长彦², 吴国华³, 张福海⁴, 赵振勇², 张科²

1. 克拉玛依区园林绿化管理局, 新疆克拉玛依 834000;
2. 中国科学院新疆生态与地理研究所, 荒漠与绿洲生态国家重点实验室, 新疆乌鲁木齐 83001;
3. 石嘴山市种子管理站, 宁夏石嘴山 753000;
4. 克拉玛依造林减排作业区, 新疆油田供水公司, 新疆克拉玛依 834000

收稿日期:2016-10-16 修回日期:2016-12-29 出版日期:2017-03-25
通讯作者: 张科,男,博士,助研.Email:zhangke@ms.xjb.ac.cn
作者简介:李艳红(1968-),女,新疆人,工程师,从事植物引种栽培及推广应用研究。主要从事生态农业研究.Email:zhangke@ms.xjb.ac.cn
基金资助:
中国科学院重点部署项目课题（KSZD-EW-Z-022-03）；克拉玛依区科技计划项目（QK2013-05）资助

Ion content and distribution in Suaeda physophora

LI Yan-hong¹, TU Jin-na¹, ZHANG Dao-yuan², WANG Lei², TIAN Chang-yan², WU Guo-hua³, ZHANG Fu-hai⁴, ZHAO Zhen-yong², ZHANG Ke²

1. Landscaping Administration Bureau of of Karamay district, Karamay 834000, Xinjiang, China;
2. State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi 830011, Xinjiang, China;
3. Shizuishan Seed Administration Station, Shizuishan 753000, Ningxia, China;
4. Afforestation and Carbon Emissions Reduction Operation Area of Karamay, Xinjiang Oilfield Water Supply Company, Karamay 834000, Xinjiang, China

Received:2016-10-16 Revised:2016-12-29 Online:2017-03-25

摘要/Abstract

摘要： 为研究真盐生植物矿质营养特征，以北疆荒漠囊果碱蓬群落为对象，通过土壤及植株调查，分析其矿质元素特征。结果显示：（1）囊果碱蓬的生长增加了0~30cm土壤的pH值、水分及盐份含量，并使盐分在土层重新分布。（2）根系相对于土壤，具有优先吸收K⁺、Mg²⁺ 养分离子的特点；叶片相对于根系，具有优先运输Cl^-、Na⁺、SO₄^2- 盐分离子的特点，同一离子在吸收和运输的选择不一致，与其在整株的功能相关。（3）Cl^-、Na⁺、SO₄^2- 积累于叶片，含量远大于K⁺、Mg²⁺、Ca²⁺ ，Cl^- 和Na⁺ 可能相伴向上运输，K⁺、Ca²⁺、Mg²⁺ 在根、茎、叶保持基本不变的比例。（4）囊果碱蓬属于SO₄ -Cl 盐积累植物，而背景土壤为Cl-SO₄ 型盐土。

关键词: 囊果碱蓬（Suaeda physophora Pall.）, 离子含量, 选择和吸收, 盐分分布, 盐生植物

Abstract: Suaeda physophora is a leaf-succulent euhalophytic shrub with tall plant height and high biomass in northern Xinjiang, China. Its content and distribution of mineral elements can reflect the ability of halophytes to absorb soil moisture and mineral nutrients. In this study, soil and plant salinity and mineral nutrients were analyzed in S. physophora communities in a saline desert area in northern Xinjiang. The results were summarized as follows:(1)pH and moisture content in the 0-30 cm root zone soil increased with the growth of S. physophora. Moreover, the content of Na⁺, Cl^- and SO₄^2- and total salt content in the soil root zone significantly increased(P ≤ 0.05), leading to redistribution of soil salinity.(2)The highest ion content was measured in leaves, while a low ion content was detected in roots and stems.(3)The contents of Cl^-, Na⁺ and SO₄² was 11.9%, 11.7%, and 3.3%, respectively, which were much higher than those of K⁺, Mg²⁺ and Ca²⁺. The distributions of Cl^-, Na⁺ and SO₄² varied greatly among the roots, stems and leaves, while those of K⁺, Mg²⁺ and Ca²⁺ were substantially the same. The contents of Cl^- and Na⁺ were similar, and they may be concomitant ions. S. physophora was a plant that accumulated SO₄ -Cl salt, and the background soil was Cl-SO₄ -dominated saline soil.(4)The roots of S. physophora took preference in selecting K⁺ and Mg²⁺ relative to soil; and the leaves took preference in transporting Cl^-, Na⁺ and SO₄^2- relative to the roots. The selection of ion absorption and transport was inconsistent and affected by the nutritional function of elements. Saline soil affects the nutrition physiology of plants. Investigating the nutritional status of naturally selected halophytes will provide useful reference data for saline agriculture. Ion absorption, distribution, and transportation within S. physophora which is grown in saline-alkali soil, are different from those within glycophytes. Mineral nutrition physiology is greatly influenced by the background soil. Secondary and micro-elements, i.e., Na, Cl, and S, become not only macro-elements but also hyperaccumulating beneficial elements in S. physophora. The levels of these elements in S. physophora are 2 to 60 000 times than those in crops. These ions are passively or actively enriched in S. physophora, compared with crops. The main damage caused by osmotic stress from soil salinity to crops is physiological drought resulted from cell dehydration. The way for plants to avoid dehydration is to accumulate organic osmotic regulators or inorganic ions. S. physophora mainly relies on absorbing and accumulating large amount of inorganic ions as osmotic regulators from the surroundings, which is the most economical way to osmotic regulation and lowering water potential, and thereby absorbing moisture from the high-salt soil solution. The roots then selectively absorb mineral nutrients based on the absorption of moisture. This is the important mechanism for euhalophytes to survive in saline soil.

Key words: Suaeda physophora, ion content, select and absorption, salt distribution, halophyte

中图分类号:

Q948.113

李艳红, 涂锦娜, 张道远, 王雷, 田长彦,吴国华, 张福海, 赵振勇, 张科. 囊果碱蓬离子含量及分布特点[J]. 干旱区地理, 2017, 40(2): 365-372.

LI Yan-hong, TU Jin-na, ZHANG Dao-yuan, WANG Lei, TIAN Chang-yan, WU Guo-hua, ZHANG Fu-hai, ZHAO Zhen-yong, ZHANG Ke. Ion content and distribution in Suaeda physophora[J]. , 2017, 40(2): 365-372.

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