单一与复合污染条件下两种敏感性植物对Cd、Zn、Pb的吸收

为了进一步研究镉、锌、铅3种重金属元素间的相互作用以及对植物吸收重金属能力的影响,在模拟单一重金属污染试验研究的基础上,采用正交回归设计方案．研究了Cd、Zn、Pb复合污染情况下紫花苜蓿和披碱草两种敏感性植物对3种重金属的吸收效应。结果表明,在单一污染条件下．银元素对紫花苜蓿生长的影响大于锌、镉、铅元素对披碱草生长的影响大于锌、镉,紫花苜蓿对于镉的吸收累积显著高于：披碱草,植物内银元素浓度最高达到1088．5mg/kg。而披碱草对于铅元素的吸收则高于紫花苜蓿。植物内铅元素浓度最高达到1345．5mg/kg。在复合污染条件下．两种植物对铅、锌和铅、镉的吸收在不同浓度范围内分别存在存在着协同效应和桔抗效应;同时两种植物对锌、银元素在实验涉及浓度范围内都存在着拮抗效应。这对于深入研究复合污染条件下重金属的土壤环境化学行为,对植物的综合毒性以及不同植物对重金属的吸收累积效应等,具有一定的参考意义。     

水培条件下几种水生植物对铅的抗性研究

水生植物能够吸收重金属污染物,净化环境且具有较高的观赏价值和经济价值。本实验选取常见的3种水生植物鸢尾、菖蒲、水葫芦,采用水培方法,研究不同植物对Pb~(2+)的抗性;以及在Pb-Zn复合污染下,Zn~(2+)的存在对水葫芦吸收Pb2+的影响。结果表明,单一污染时水葫芦对较高浓度的含铅废液表现出一定的抗性,菖蒲对中低浓度含铅废液抗性较好,鸢尾次之。在复合污染条件下,水葫芦对铅、锌的吸收在不同浓度范围内分别存在着协同效应和拮抗效应。植物不同组织对铅的吸收累积程度不同,3种水生植物体内的重金属含量均呈现出地下部分高于地上部分,对重金属铅的体内转移能力不明显,不属于超富集植物,因此这3种植物均不适合处理高浓度含铅废液。     

施用尿素对土壤中Cd、Pb形态分布及植物有效性的影响

采用室外盆栽试验,研究了在镉(25mg·kg-1)、铅(1000mg·kg-1)单一污染及其复合污染的土壤中,施用不同剂量尿素(0、100、200、400、800mg·kg-1)对小麦根际和非根际土壤镉、铅形态、小麦植物体镉、铅浓度的影响,为重金属污染土壤的防治提供依据。结果表明:增加尿素施用水平显著提高了小麦不同部位镉、铅浓度,尿素施用促进小麦对镉、铅的吸收与其对土壤中镉、铅形态分布的影响紧密相关,尿素施用引起土壤pH下降,提高土壤中交换态镉、铅含量,而交换态是最易被植物吸收利用的部分,这是尿素施用提高镉、铅植物有效性的主要原因;与单一污染相比,镉、铅复合污染抑制了小麦对铅的吸收,但促进了小麦对镉的吸收。     

土壤中镉、铅、锌及其相互作用对作物的影响

通过作物盆栽模拟试验(砂壤质褐土、pH值8.2)揭示：土壤中分别施入镉(CdCl2)、铅[Pb(CH3COO)2]或锌(ZnSO4)其影响表现为,植物各器官镉的含量超过对照植物的数倍至500倍。土壤镉浓度<5ppm和<10ppm分别造成某些蔬菜和水稻的污染。铅主要积累在植物根部,土壤铅污染对作物的影响较小。锌主要积累在植物叶片和根部,对水稻产生生长抑制的土壤锌浓度临界值不大于200ppm,此浓度对旱作无影响。土壤中同时施入镉和铅,植物对镉的吸收增加。而土壤中镉的增加却减少了植物体内铅的含量。土壤中由于镉、锌或铅、锌相互作用的结果,水稻对它们的吸收都有增加。在旱地土壤锌浓度的增高,降低了植物对镉、铅的吸收。镉、铅、锌同时施入土壤由于相互作用的结果,除锌之外,植物对镉、铅的吸收有明显下降。评价土壤重金属污染,不仅要看它们的含量及其存在形态,而且要分析它们之间的相互作用(促进或拮抗)特点。     

5种湿地植物对土壤重金属的富集转运特征

选择芦苇、水葱、千屈菜、扁秆藨草、长苞香蒲5种湿地植物进行盆栽实验,比较它们对土壤中的5种重金属镉、铬、汞、铅、锌的富集特性,分析重金属在各植物体和土壤中的动态分布,以评价所测植物对土壤中重金属的综合富集能力,为利用植物修复金属污染土壤提供理论依据和技术支持。结果表明:(1)种植湿地植物对土壤重金属的富集效果显著高于无植物对照,且随着处理时间的延长,土壤中重金属镉、铬、汞、铅、锌的含量均呈下降趋势。(2)湿地植物对重金属镉、铬、汞、铅、锌的富集效果差异显著,其中水葱根部对重金属镉的富集系数最大,芦苇根部对重金属铬、汞、铅、锌的富集系数均最大,千屈菜、扁秆藨草和长苞香蒲根部对5种重金属的富集系数均较小;芦苇地上部分对金属镉的富集系数最大,千屈菜地上部分对金属铬、汞、铅的富集系数均最大,水葱地上部分对金属锌的富集系数最大。(3)5种湿地植物对重金属镉、铬、汞、铅、锌的转移系数差异显著,其中扁秆藨草对土壤中镉、铬、铅、锌的转移系数均为最大,对铬和锌的转移系数均大于1,长苞香蒲对铬的转移系数大于1,仅次于扁秆藨草。其他3种植物对5种重金属的转移系数均小于1。研究表明,5种湿地植物对重金属Cd、Cr、Hg、Pb、Zn都有富集和转移的能力,但不同植物对不同重金属的富集效果不同。     

几种重金属(Pb、Zn、Cd、Cu)的超富集植物种类及增强植物修复措施研究进展

近年来土壤重金属污染问题越来越严重, 植物修复技术以其安全、廉价的特点正成为研究和开发的热点, 国内外对利用超富集植物来修复土壤重金属污染的研究已有大量报道。对超富集植物概念的提出及超富集植物吸收富集重金属的机理进行了归纳总结, 主要就铅、锌、镉和铜四种重金属超富集植物的相关研究进展进行了分类、归纳与总结, 同时还对增强植物修复效果的措施进行了探讨, 以期为进一步合理有效利用植物修复土壤主要重金属污染提供一定的参考依据。     

蜈蚣草耐铅、铜、锌毒性和修复能力的研究

重金属复合污染是主要土壤污染类型之一。为了探明蜈蚣草修复土壤重金属复合污染的能力,土培试验研究了分别添加不同浓度铅、铜、锌条件下蜈蚣草生物量变化,结果表明,不同浓度铅和较低浓度锌处理下蜈蚣草生物量呈显著性地增加,土壤Pb、Zn添加浓度分别为1750mg／kg和1350mg／kg,蜈蚣草生物量最大。说明蜈蚣草有极强的耐Pb、Zn毒性能力,能在较高有效态Pb或Zn污染土壤上正常生长。蜈蚣草具有一定的耐Cu毒性能力,在Cu耐性方面,蜈蚣草可能存在生态型的差异。以上结果说明,利用蜈蚣草修复萃取Pb—As,Zn—As,Cu-As等复合污染土壤上As有重要的意义。     

木本植物对大气重金属污染物耐性的研究

本文在污染现场调查研究、试验研究和单一毒物接触试验的大量数据基础上,论述了木本植物对大气重金属污染物一一铅、镉、铜、锌的耐性。查明了大气重金属污染物引起叶片可见伤害症状需要很高的剂量。糖槭以2000ppm硝酸铅溶液浸泡涂抹枝叶,三天后出现轻度可见伤害症状,叶中铅积累量高达802ppm。旱柳以500ppm氯化镉溶液浸泡涂抹枝叶,叶中积累量达66ppm,十天内未出现可见症状。大气重金属污染物——铅、镉、铜、锌对叶片造成的急性伤害症状是相似的,而与土壤中相同污染物引起的急性伤害具有差别。木本植物对大气重金属污染物的耐性很强,在以大气重金属污染为主的复合污染现场,一些幼龄树木的叶片吸铅量达500—800ppm,超过背景浓度的120倍;吸镉量10—18ppm,超过背景浓度的139倍,吸铜量100—239ppm,超过背景浓度的5—12倍,吸锌量500—700ppm,超过背景浓度的9—20倍只出现较轻的受害症状。在相对清洁区,对幼树叶片进行单一毒物接触试验,一些主要绿化树木的叶片吸铅量达200—600ppm,吸镉量20—60ppm并不出现可见症状。木本植物对大气重金属污染物具有较强的耐性,因而为生物防治大气重金属污染开辟了广阔的前景。     

干旱胁迫下镉处理对互叶醉鱼草幼苗生长、镉积累及光合生理的影响

为探究干旱条件下,互叶醉鱼草(Buddleja alternifolia Maxim.)幼苗对重金属镉胁迫的生长及光合生理响应机制,以两年生互叶醉鱼草幼苗为试验材料,设置对照与干旱两个水分处理组(土壤相对含水率分别为:65%—60%,35%—30%),每个水分处理条件下再分别设置3个镉处理浓度(0.28、(0.6+0.28)、(1.2+0.28)mg/kg),共6个处理。测定不同水分及镉处理对互叶醉鱼草生长、生物量、光合参数及体内重金属含量的影响。结果表明:干旱与镉复合胁迫下植物的存活率为100%。镉胁迫、干旱与镉复合胁迫均不同程度抑制了互叶醉鱼草幼苗生长、生物量积累、植株的光合作用及叶绿素含量,且其光合和叶绿素含量的降幅明显大于单一镉胁迫。镉胁迫下,互叶醉鱼草幼苗单株最高镉富集量为69.33 mg/kg,而复合胁迫下单株最高镉富集量为50.68 mg/kg。以上结果表明:干旱胁迫能够加重镉胁迫对植物的影响,使复合胁迫下互叶醉鱼草生长、光合生理及镉富集能力下降。但单一镉胁迫下,互叶醉鱼草对镉具有更强的耐受性,并有较高的生物富集能力,且干旱与Cd复合胁迫下互叶醉鱼草幼苗仍有一定的镉积累量。因此在干旱半干旱区园林绿化以及Cd污染地区的生态建设中,互叶醉鱼草是一种具有巨大应用潜力和前景的灌木树种。     

重金属（铜、镉、锌和铅）对海水无机碳体系影响的模拟研究

通过室内模拟实验,研究了孔石莼和重金属(铜、镉、锌和铅)共同作用下,海水无机碳体系及碳源汇格局的变化.结果表明,t=7d时,无机碳体系各参数的变化幅度(Δ)与重金属种类和浓度有关.与对照相比,低浓度(<1μmol · L-1)的重金属添加组中,DIC、HCO-3 和PCO2的下降幅度都很明显(P<0.01* *).当铜、镉浓度大于"转折浓度"后, DIC、HCO-3和Pco2 均要大于初始值,其增幅随着重金属浓度的增加而增大.对于锌和铅,二者浓度高达50μmol · L-1时,水体中无机碳各参数与初始值相比仍呈现下降趋势.此外,当重金属浓度和种类不同时,水体中的碳源汇格局亦做不同的变化.当铜和镉浓度小于转折浓度时,水体表现为大气CO2的汇;而当铜和镉超出转折浓度时,水体会由大气CO2的汇过渡到源,并且当水体成为CO2的源后,其CO2的释放量是随着铜、镉浓度的增加而增大.在本实验设计的各浓度锌、铅添加组水体始终表现为碳汇,但当锌、铅浓度分别高于15μmol · L-1和20μmol · L-1时,其碳汇强度开始小于对照组(P<0.05*).     

Interactive effects of cadmium,lead and zinc on root growth of two metal tolerant genotypes ofHolcus lanatus L.

Lead and zinc tolerant genotypes ofHolcus lanatus L. were grown in culture solution at different cadmium, lead and zinc concentrations, and combinations. In all treatments, an increased inhibition of root length with increasing concentrations of heavy metals was observed. Growth of genotype 1 was better than that of genotype 2 in all treatments, suggesting that genotype 1 is more tolerant. The better root growth of genotype 1, at different cadmium concentrations, than that of genotype 2, indicated the existence of a co-tolerance or greater tolerance of genotype 1 to cadmium. Heavy metal combinations resulted in increased lead or zinc uptake by plants, while cadmium was decreased. In a lead-zinc combination, decreased lead and increased zinc uptake were detected. The different interactive effects of heavy metals on root growth of genotype 1 (additive or synergistic) and genotype 2 (additive or antagonistic) may suggest their differential susceptibility to the above metals.     

Uptake of six heavy metals by oat as influenced by soil type and additions of cadmium,lead, zinc and copper

Summary The influence of heavy metal additions on availability and uptake of cadmium, lead, zinc, copper, manganese and iron by oat was studied. The experiments were carried out as pot experiments using sandy loam, sandy soil and organic soil. Selective extractants were used to remove metals held in different soil fractions.Lead and copper were preferently bound by organics and oxides, zinc by oxides and inorganics, and cadmium by inorganics and organics.Addition of cadmium to the soils resulted in higher cadmium concentrations in all plant parts but lower concentrations of lead, zinc, copper, manganese and iron, and the accumulation indexes of these metals were also lower when cadmium was added to the soil.Addition of cadmium plus lead, zinc and copper resulted in higher cadmium concentrations in leaves and straw of plants grown in sandy loam and sandy soil, but lower concentrations when plants were grown in organic soil as compared with the results when cadmium was added separately. The transfer of cadmium, lead, zinc and copper from soil to plant was greatest from sandy soil, and zinc and cadmium were more mobile in the plant than were lead and copper.Cadmium concentrations in leaves correlated significantly with CaCl₂ and CH₃COOH extractions in sandy loam and sandy soil and with CH₃COOH extractions in organic soil.Generally, the total metal uptake was lowest from organic soil.     

Influence of heavy metals on the accumulation of trimethylglycine, putrescine and spermine in food plants

Summary. Increased contents of cadmium (Cd), lead (Pb), zinc (Zn) and other heavy metals in barley plants enhanced the accumulation of trimethylglycine (betaine), putrescine and spermine. Higher contents of heavy metals in barley were caused by soil enrichment with heavy metals and by soil salinity. The highest accumulation of spermine and betaine (increase 3-fold or 5-fold in comparison to untreated soil substrates) was obtained at the highest concentration of heavy metals in plants. Consequently the betaine-N / protein-N-ratio and the spermine-N / protein-N-quotient increased 3-fold in plants with high heavy metal contents. The biomass formation was not changed significantly by the different experimental treatments. Received January 28, 2000 Accepted March 1, 2000     

Microbial leaching of zinc concentrate in fresh‐water microcosms: Comparison between aerobic and oxygen‐limited conditions

Microbially mediated leaching and solubilization of zinc ore concentrate by native aquatic microbial communities incubated under aerobic and oxygen‐limited conditions were examined in static microcosms consisting of stream sediment and water. Sterile controls provided information on abiotic sulfide oxidation and leaching of zinc, lead, cadmium, and copper. The flux of these heavy metals from the sediments to the water column was greatest under biotic oxygen‐limited conditions. When calculated as the percentage of total metal available in zinc concentrate‐amended microcosms, the order of metal solubilization under oxygen‐limited conditions was lead, copper, zinc, and cadmium. Under biotic aerobic conditions, the order of solubilization was zinc, lead, cadmium, and copper. This study indicates that aquatic heterotrophs are capable of leaching and solubilizing metallic sulfides under conditions of neutral to slightly acidic pH and are effective in releasing heavy metals to the water column under oxygen‐limited conditions.     

Phytochelatins as biomarkers for heavy metal stress in maize (Zea mays L.) and wheat (Triticum aestivum L.): combined effects of copper and cadmium

Heavy metal contaminated soils often show increased levels of more than one metal, e.g. copper (Cu), cadmium (Cd), zinc (Zn), lead (Pb) or nickel (Ni). In case such soils are used for crop production, prediction of yield reduction or quality decline due to heavy metals in the soil is inadequate when based only on chemical soil analysis. The use of biomarkers such as phytochelatins (PC), non-protein thiols specifically induced in plants upon exposure to heavy metals, may be an additional tool or diagnostic criterion in heavy metal research and in practice. In the present work, Cu and Cd uptake and induction of PC synthesis are studied with hydroponically grown maize and wheat plants exposed to mixtures of the two metals. We observed a close positive relationship between the concentrations of Cd and PC in the plant shoot material. A decreased shoot concentration of Cd after addition of Cu, due to metal competition at common root absorption sites, coincided with lower shoot PC levels. Also differences in metal uptake and xylary metal transport among the two plant species were reflected in corresponding differences in PC concentration. The observed direct relationship between shoot PC concentration and the degree of metal-induced growth inhibition makes the use of PC promising for the purpose tested for.     

Heavy metal stress. Activation of distinct mitogen-activated protein kinase pathways by copper and cadmium

Excessive amounts of heavy metals adversely affect plant growth and development. Whereas some regions naturally contain high levels of heavy metals, anthropogenic release of heavy metals into the environment continuously increases soil contamination. The presence of elevated levels of heavy metal ions triggers a wide range of cellular responses including changes in gene expression and synthesis of metal-detoxifying peptides. To elucidate signal transduction events leading to the cellular response to heavy metal stress we analyzed protein phosphorylation induced by elevated levels of copper and cadmium ions as examples for heavy metals with different physiochemical properties and functions. Exposure of alfalfa (Medicago sativa) seedlings to excess copper or cadmium ions activated four distinct mitogen-activated protein kinases (MAPKs): SIMK, MMK2, MMK3, and SAMK. Comparison of the kinetics of MAPK activation revealed that SIMK, MMK2, MMK3, and SAMK are very rapidly activated by copper ions, while cadmium ions induced delayed MAPK activation. In protoplasts, the MAPK kinase SIMKK specifically mediated activation of SIMK and SAMK but not of MMK2 and MMK3. Moreover, SIMKK only conveyed MAPK activation by CuCl(2) but not by CdCl(2). These results suggest that plants respond to heavy metal stress by induction of several distinct MAPK pathways and that excess amounts of copper and cadmium ions induce different cellular signaling mechanisms in roots.     

Arabidopsis arenosa (Brassicaceae) from a lead–zinc waste heap in southern Poland – a plant with high tolerance to heavy metals

The morphological traits and tolerance to heavy metals (zinc, cadmium and lead) of two populations of Arabidopsis arenosa (Brassicaceae) were compared. One population was from a zinc–lead waste heap in Bolesław near Olkusz (southern Poland), the other one from the Kampinoski National Park (central Poland). Biometric measurements were done in the field and repeated after cultivation under controlled conditions (garden soil, phytotron chamber). Significant heritable morphological differences between the two populations were found. The plants from the waste-heap are smaller in comparison with the reference population, and their leaves are narrower, thicker with fewer trichomes, indicating. genetic adaptation to xerothermic conditions. The level of tolerance to heavy metals (zinc, cadmium, and lead) was compared by the root test. Very high tolerance to the three metals tested was found in the waste-heap population. Its tolerance exceeded that of four other predominant plant species populations growing on the same waste heap that had previously been tested in our laboratory. We consider the waste-heap population of A. arenosa to be a very suitable ecotype for the study of heavy metal tolerance mechanisms in plants. Responsible Editor: SE: Henk Schat.     

Assessing Plant Phytoextraction Potential Through Mathematical Modeling

One of the most serious and long-term consequences of environmental pollution is heavy metal contamination of soils. Elements such as zinc, cadmium, lead, nickel, and chromium are being released into the environment by many industrial processes and have now reached concentrations that are of concern. Phytoremediation is a new, low-cost, and environmentally friendly technique that relies on the natural properties of some plants to clean-up the ground through their ability to take up metals from the soil. Hyperaccumulator plants, capable of accumulating metals far in excess of any normal physiological requirement, represent a most promising tool for metal phytoextraction, but the in field establishment of their conditions for utilization needs a long period because of the plant life-cycle. The use of a mathematical model is proposed to process growth and uptake data from in vitro experiments for a rapid assessment of the time and concentration parameters for the deployment of hyperaccumulator plants for phytoextraction purposes. This preliminary research has been carried out using Alyssum bertolonii Desv., a nickel hyperaccumulator endemic to Italian serpentine soils.     

Heavy metals in some Chinese herbal plants

The concentrations of nine heavy metals, cadmium, cobalt, copper, iron, manganese, nickel, lead, zinc and mercury in 42 Chinese herbal medicinal plants were determined. Generally, all the samples studied had, relative to the other trace metals, higher concentrations of iron, manganese, and zinc. The concentration range of the metals determined was comparable to that in many of the East Asian vegetables and fruits. A few samples were found to contain relatively higher concentrations of the toxic metals such as cadmium, lead, and mercury. This was probably caused by contamination during air-drying and preservation.