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1.
菱镁矿粉尘污染土壤机理及其植物修复   总被引:1,自引:0,他引:1  
综述了菱镁矿粉尘对土壤的污染和植物的毒害作用机理,分析了镁粉尘污染土壤的改良途径,探讨了植物修复的可行性和关键技术.菱镁矿在开采、生产加工过程中产生的大量粉尘,主要成分为MgCO3和MgO,镁粉尘对土壤的污染和植物的毒害作用主要是通过碱化、板结土壤,以及使土壤中的水溶性钙、镁离子比例失调而造成的.虽然菱镁矿粉尘污染土壤的植物修复研究鲜见报道,但通过植物吸收、植物代谢和植物积累等作用去除土壤中的过量镁具有较强的可行性.  相似文献   

2.
类固醇雌激素(steroidal estrogens, SEs)作为典型的内分泌干扰物,在环境介质中被广泛检出,其进入生物体后可模拟细胞内源性激素作用对生物体生长、发育、生殖等产生不利影响,因此越来越引起关注。目前关于SEs的研究报道多集中于粪便、土壤、水体等介质中的检出及环境行为,以及SEs在水生生物体内的迁移和转化,其累积效应及其机制研究较为系统和全面。相较而言,SEs在土壤-植物体系中的迁移累积报道较少,但是对于掌握农田系统中SEs迁移转化的需求更为迫切。结合现有的国内外相关研究,总结了SEs在土壤-植物体系中的吸收累积和迁移转化行为特征,概述了植物吸收代谢SEs的影响因素以及SEs对植物生长发育的毒理效应。目前针对SEs的植物体吸收大多数仍基于室内模拟实验,对于其在土壤-植物多相态体系中迁移转化机理尚不清楚。因此,对今后的研究方向提出以下几点建议:(1)除室内模拟实验外,对实际土壤-植物系统中的研究更具价值,特别是SEs土壤-土壤水-植物多相态体系中的迁移转化等过程;(2)应结合SEs的来源,探究畜禽粪便、城市污泥及污水等不同源SEs对植物吸收、累积污染物的影响及污染风险;(3)加强对农作物体内SEs残留的监测和风险评估,制定SEs农作物检出及人体摄入的相关标准。  相似文献   

3.
低放核素污染土-水介质的植物修复研究进展   总被引:2,自引:0,他引:2  
张晓雪  王丹  闻方平 《西北植物学报》2008,28(12):2571-2574
植物修复技术是利用植物根系吸收水分和养分的过程来吸收和转化土壤和水体中的污染物,以期达到清除,修复和治理的目的,是用于对土壤-水体中重金属和放射性核素污染清除的生态技术.本文就放射性核素的来源、污染现状、植物对放射性核素的积累筛选以及对污染土壤的修复研究进行综述,以明确植物修复技术在改善环境中的作用,为进一步筛选超积累植物并探讨植物对放射性核素污染的修复机理提供参考.  相似文献   

4.
<正>近年来,随着工农业及采矿业的迅速发展,重金属对水体环境的污染已经成为了全球性的环境问题[1,2]。镉是生物有机体的非必需元素,在环境中以自由离子和配合物的形式存在,且易被浮游生物吸收。被吸收后的镉一部分随着浮游生物的死亡而进入沉积物,另一部分则随着食物链进行传递,最后被人体吸收,从而对人体产生毒害作用,因此被认为是最典型的一种重金属污染物[3]。研究表明镉能够抑制植物的生长,破坏叶绿素的合成,损害放氧复合体(OEC)锰稳定蛋白(MSP)的结构[4],或取代放氧复合体中的Ca2+和叶绿素a的Mg2+等[5]。水  相似文献   

5.
镉在土壤-植物-人体系统中迁移积累及其影响因子   总被引:53,自引:0,他引:53  
环境镉(Cd)污染对微生物、植物、动物和人体均可产生较大的危害。食物链是镉对普通人群造成健康危害的主要途径之一。污染土壤中的镉通过植物根系吸收与体内转运最终在植物可食部分中积累。Cd通过食物链进人人体并在体内蓄积受许多因素的影响,这些影响因素主要有3个方面:土壤性质(土壤含镉量、pH、有机质、粘土矿物和土壤养分状况),植物特性(包括基因型差异、根际过程和植物生理机制)和人体微量元素营养状况等因素。本文就镉在食物链中迁移积累及其调控机理的研究进展进行简要的综述。  相似文献   

6.
转基因植物对有机污染物的吸收、转化和降解   总被引:7,自引:0,他引:7  
有机污染物是土壤、水体和大气环境的重要污染物.利用和加强植物修复作用是控制环境污染的有效途径.近年来,一些具有修复功能的外源基因被陆续引入到植物中,使转基因植物的生物修复能力大大增强.文章介绍了植物对污染环境中有机污染物,尤其是持久性有机污染物(POPs)的吸收、转化和降解作用,阐述了转基因植物用于被污染环境修复方面的研究进展和应用前景.  相似文献   

7.
沉水植物对重金属的积累净化和受害机理研究主要集中在4个方面: (1)沉水植物对重金属(包括放射性物质)的吸收、积累和净化作用; (2)沉水植物对重金属的抗性强弱和机制; (3)沉水植物用于监测水体的重金属污染; (4)沉水植物的重金属胁迫机制, 包括重金属对植物形态和显微结构的损伤, 对植物抗氧化酶系统的影响, 对植物的叶绿素、蛋白质以及光合与呼吸作用等生理生化指标的影响, 植物对重金属的吸附和转运动力学, 以及Zn对Cd毒害的拮抗等。  相似文献   

8.
氟的危害及控制   总被引:8,自引:0,他引:8  
环境中氟的危害是环境科学及卫生学界极为关注的问题。氟的过多吸收 ,对动植物及人体会产生危害[1 ,2 ] 。研究氟危害的表现特征及机理 ,目的是为了控制或减轻氟危害。综合评价氟的测定方法 ,在氟污染调查和环境质量评价中 ,有切实的实用价值。1 氟对植物及土壤微生物的毒害作用土壤氟污染对作物的危害是慢性积累的生理障碍过程。氟能抑制作物的新陈代谢、呼吸作用[3] 及光合作用[2 ] ,抑制新陈代谢过程中马来酸脱氢酶的活性[4] 。氟对作物的危害主要表现为干物质积累量少、产量降低、分蘖少、成穗率低、光合组织受损伤 ,出现叶尖坏死 ,叶…  相似文献   

9.
无机砷在植物体内的吸收和代谢机制   总被引:2,自引:0,他引:2  
砷污染已成为全球非常突出且急需解决的环境问题,严重威胁人类健康和环境安全.在自然环境和土壤系统中,砷的存在形态相当复杂,但植物砷毒害主要源于As(Ⅴ)和As(Ⅲ)暴露.As(Ⅴ)通过Pi的吸收通道被植物根系吸收,并在还原酶(AR)作用下被快速还原为As(Ⅲ).As(Ⅲ)通过NIP蛋白通道进入植物体内,在砷甲基转移酶(ArsM)的作用下转化为甲基化砷或与谷胱甘肽(GSH)、植物螯合肽(PC)等多肽的巯基螯合封存在根部液泡或转运到地上部分,从而起到砷解毒的作用.同时,植物吸收的一部分砷也可外排到外部介质.本文以农作物尤其是水稻为主线,详述了As(Ⅴ)和As(Ⅲ)吸收、外排及As(Ⅴ)还原、As(Ⅲ)甲基化、螯合作用的最新研究进展,并提出了今后的研究重点.  相似文献   

10.
四溴双酚-A的代谢转化与生态毒理效应研究进展   总被引:5,自引:0,他引:5  
四溴双酚-A(TBBPA)是全球产量最大、使用最广泛的溴化阻燃剂,主要应用于印刷线路板及ABS、HIPS等多种材料的阻燃.随着它的大量使用,引起了大气、水体、沉积物和土壤等环境介质及相关生态系统的严重污染.本文综合了国内外相关研究,对其降解性能、代谢转化以及生态毒理效应3方面进行了综述,并对TBBPA今后的研究方向进行了探讨,以推进我国在此方面的研究.  相似文献   

11.
Many crops cultivated in mining areas have been found to accumulate high levels of antimony (Sb) in their edible parts, thereby causing potential risks to human health. Understanding the behaviours of Sb in plants is important, particularly the mechanisms involved in its uptake, toxicity, detoxification and accumulation in crops. Many factors affect the uptake of Sb in plants, including water management, Sb speciation and some coexisting ions in soils. At present, the mechanisms of Sb uptake by plants have not been fully elucidated so far. The uptake of Sb has been proposed to occur mainly through the passive pathway; however, it is possible that an active pathway exists as well. Antimony can damage plants, including growth retardation, inhibition of photosynthesis, decreases in the uptake of certain essential elements and decreases in the synthesis of certain metabolites. Plants often have defence mechanisms to alleviate Sb toxicity; e.g., a highly efficient antioxidative system and the ability to immobilise Sb in the cell wall or compartmentalise Sb in the cytosol. Such mechanisms have been widely reported in Sb-tolerant and Sb-accumulating plants. In view of the above knowledge, several questions remain: (1) What is the actual uptake pathway of Sb in plants? (2) Does Sb participate in redox reactions within plants? (3) What is the role of metabolic reactions of Sb in Sb toxicity to plants? (4) Can Sb be methylated, and if so, how? (5) How does Sb induce bursts of reactive oxidative species (ROS)?  相似文献   

12.
土壤-植物系统是生物圈的基本结构单元,土壤与植物之间存在密切的相互反馈。土壤退化导致植物面临各种非生物胁迫,植物的生理代谢遭到干扰,养分获取受到抑制。蚯蚓被称为“生态系统的工程师”。蚯蚓能够通过调控土壤物理-化学-生物学特性,改良退化土壤(盐碱土、重金属和有机污染物污染土壤),缓解植物所受胁迫,增加土壤养分有效性,促进植物生长,并通过自身分泌的信号物质提高植物的抗逆性。蚯蚓对土壤-植物系统的生态修复作用,对于改善植物生长环境、维持土壤生态系统健康和稳定具有重要意义。  相似文献   

13.
Using pot experiments, we investigated the uptake of antimony (Sb) by sunflower (Helianthus annuus L. cv. Iregi), and maize (Zea mays L. cv. Magister) in two different soils, a potting mix and an agricultural soil. In one treatment Sb was added to the experimental soils as KSb(OH)6 (“SbV-treatment”) and in the other as Sb2O3 (“SbIII-treatment”). Soluble soil Sb concentrations were linearly related to the applied Sb rates, ranging from 0.02 (controls) to 175 mg L?1 soil solution. Accumulation of Sb tended to be slightly higher in the SbV treatment in sunflower, while no difference in Sb uptake between the two Sb treatments was found in maize. The half maximal effective concentration (EC50) values derived from the dose-response curves were higher for the SbV than for the SbIII treatment when they were related to soluble soil Sb concentrations, but differences became insignificant when they were related to shoot Sb concentrations. Maize was substantially more sensitive to Sb toxicity than sunflower, indicating physiological differences in Sb tolerance between the two plant species. Our results show that on soils with high Sb contamination, as often found in shooting ranges, plants may suffer from Sb toxicity.  相似文献   

14.
15.
Plant nanotoxicology   总被引:4,自引:0,他引:4  
The anthropogenic release of nanoparticles (NPs) to the environment poses a potential hazard to human health and life. The interplay between NPs and biological processes is receiving increasing attention. Plants expose huge interfaces to the air and soil environment. Thus, NPs are adsorbed to the plant surfaces, taken up through nano- or micrometer-scale openings of plants and are translocated within the plant body. Persistent NPs associated with plants enter the human food chain. In this Opinion, we document the occurrence and character of NPs in the environment and evaluate the need for future research on toxicological effects. Plant nanotoxicology is introduced as a discipline that explores the effects and toxicity mechanisms of NPs in plants, including transport, surface interactions and material-specific responses.  相似文献   

16.
Cadmium (Cd) is an inorganic mineral in the earth's crust. Cadmium entry into the environment occurs through geogenic and anthropogenic sources. Industrial activities including mining, electroplating, iron and steel plants, and battery production employ Cd during their processes and often release Cd into the environment. When disseminated into soil, Cd can be detrimental to agro-ecosystems because it is relatively mobile and phytotoxic even at low concentrations. Cadmium's phytotoxicity is due to reductions in the rate of transpiration and photosynthesis and chlorophyll concentration resulting in retardation of plant growth, and an alteration in the nutrient concentration in roots and leaves. In response to Cd toxicity, plants have developed protective cellular mechanisms such as synthesis of phytochelatins and metallothioneins, metal compartmentalization in vacuoles, and the increased activity of antioxidant enzymes to neutralize Cd-induced toxicity. While these direct protective mechanisms can help alleviate Cd toxicity, other indirect mechanisms such as microelements (zinc, iron, manganese, and selenium) interfering with Cd uptake may decrease Cd concentration in plants. This comprehensive review encompasses the significance of Cd, portals of contamination and toxicity to plants, and implications for crop production. Various mitigation strategies with the beneficial effects of zinc, iron, manganese, and selenium in activating defence mechanisms against Cd stress are discussed. Furthermore, this review systematically identifies and summarises suitable strategies for mitigating Cd-induced toxicity in plants.  相似文献   

17.
Water is vital for plant growth, development and productivity. Permanent or temporary water deficit stress limits the growth and distribution of natural and artificial vegetation and the performance of cultivated plants (crops) more than any other environmental factor. Productive and sustainable agriculture necessitates growing plants (crops) in arid and semiarid regions with less input of precious resources such as fresh water. For a better understanding and rapid improvement of soil–water stress tolerance in these regions, especially in the water-wind eroded crossing region, it is very important to link physiological and biochemical studies to molecular work in genetically tractable model plants and important native plants, and further extending them to practical ecological restoration and efficient crop production. Although basic studies and practices aimed at improving soil water stress resistance and plant water use efficiency have been carried out for many years, the mechanisms involved at different scales are still not clear. Further understanding and manipulating soil–plant water relationships and soil–water stress tolerance at the scales of ecology, physiology and molecular biology can significantly improve plant productivity and environmental quality. Currently, post-genomics and metabolomics are very important in exploring anti-drought gene resources in various life forms, but modern agriculturally sustainable development must be combined with plant physiological measures in the field, on the basis of which post-genomics and metabolomics have further practical prospects. In this review, we discuss physiological and molecular insights and effects in basic plant metabolism, drought tolerance strategies under drought conditions in higher plants for sustainable agriculture and ecoenvironments in arid and semiarid areas of the world. We conclude that biological measures are the bases for the solutions to the issues relating to the different types of sustainable development.  相似文献   

18.
Plant Cell, Tissue and Organ Culture (PCTOC) - The contamination of water and soil by arsenic (As) is a global environmental, health, and agricultural issue. The study of As toxicity in plants and...  相似文献   

19.
Heavy metal contamination of soil, aqueous waste stream and ground water causes major environmental and human health problems. Heavy metals are major environmental pollutants when they are present in high concentration in soil and show potential toxic effects on growth and development in plants. Due to unabated, indiscriminate and uncontrolled discharge of hazardous chemicals including heavy metals into the environment, plant continuously have to face various environmental constraints. In plants, seed germination is the first exchange interface with the surrounding medium and has been considered as highly sensitive to environmental changes. One of the crucial events during seed germination entails mobilization of seed reserves which is indispensable for the growth of embryonic axis. But, metabolic alterations by heavy metal exposure are known to depress the mobilization and utilization of reserve food by affecting the activity of hydrolytic enzymes. Some plants possess a range of potential mechanisms that may be involved in the detoxification of heavy metals by which they manage to survive under metal stress. High tolerance to heavy metal toxicity could rely either on reduced uptake or increase planned internal sequestration which is manifested by an interaction between a genotype and its environment. Such mechanism involves the binding of heavy metals to cell wall, immobilization, exclusion of the plasma membrane, efflux of these toxic metal ions, reduction of heavy metal transport, compartmentalization and metal chelation by tonoplast located transporters and expression of more general stress response mechanisms such as stress proteins. It is important to understand the toxicity response of plant to heavy metals so that we can utilize appropriate plant species in the rehabilitation of contaminated areas. Therefore, in the present review attempts have been made to evaluate the effects of increasing level of heavy metal in soils on the key behavior of hydrolytic and nitrogen assimilation enzymes. Additionally, it also provides a broad overview of the strategies adopted by plants against heavy metal stress.  相似文献   

20.
Many plants have been known to be contaminated and accumulate plasticizers from the environment, including water sources, soil, and atmosphere. Plasticizers are used to confer elasticity and flexibility to various fiber and plastic products. Consumption of plasticizers can lead to many adverse effects on human health, including reproductive and developmental toxicity, endocrine disruption, and cancer. Herein, we report for the first time that two plasticizers, bis(2-ethylhexyl) terephthalate (DEHT) and bis(2-ethylhexyl) phthalate (DEHP), have been isolated from the leaves of Capparis spinosa L. (the caper bush), a plant that is widely used in food seasonings and traditional medicine. 297 mg/kg of DEHT and 48 mg/kg of DEHP were isolated from dried and grounded C. spinosa L. leaves using column chromatography and semi-preparative high-performance liquid chromatography. Our study adds to the increase in the detection of plasticizers in our food and medicinal plants and to the alarming concern about their potential adverse effects on human health.  相似文献   

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