Mechanisms of arsenic hyperaccumulation in Pteris vittata. Uptake kinetics, interactions with phosphate, and arsenic speciation

The mechanisms of arsenic (As) hyperaccumulation in Pteris vittata, the first identified As hyperaccumulator, are unknown. We investigated the interactions of arsenate and phosphate on the uptake and distribution of As and phosphorus (P), and As speciation in P. vittata. In an 18-d hydroponic experiment with varying concentrations of arsenate and phosphate, P. vittata accumulated As in the fronds up to 27,000 mg As kg(-1) dry weight, and the frond As to root As concentration ratio varied between 1.3 and 6.7. Increasing phosphate supply decreased As uptake markedly, with the effect being greater on root As concentration than on shoot As concentration. Increasing arsenate supply decreased the P concentration in the roots, but not in the fronds. Presence of phosphate in the uptake solution decreased arsenate influx markedly, whereas P starvation for 8 d increased the maximum net influx by 2.5-fold. The rate of arsenite uptake was 10% of that for arsenate in the absence of phosphate. Neither P starvation nor the presence of phosphate affected arsenite uptake. Within 8 h, 50% to 78% of the As taken up was distributed to the fronds, with a higher translocation efficiency for arsenite than for arsenate. In fronds, 49% to 94% of the As was extracted with a phosphate buffer (pH 5.6). Speciation analysis using high-performance liquid chromatography-inductively coupled plasma mass spectroscopy showed that >85% of the extracted As was in the form of arsenite, and the remaining mostly as arsenate. We conclude that arsenate is taken up by P. vittata via the phosphate transporters, reduced to arsenite, and sequestered in the fronds primarily as As(III).

Variation in arsenic accumulation - Hyperaccumulation in ferns and their allies

A range of fern species (45) and their allies, Equisetum (5) and Selaginella (2) species and Psilotum nudum were screened for their ability to hyperaccumulate arsenic, to develop a phylogenetic understanding of this phenomenon. A number of varieties (5) of a known arsenic hyperaccumulator Pteris cretica were additionally included in this study. This study is the first to report members of the Pteris genus that do not hyperaccumulate arsenic, Pteris straminea and tremula. A phylogenetic basis for arsenic accumulation in ferns was investigated. Some orders can accumulate more arsenic than others. Although members of the Equisetales and Blechnales did not hyperaccumulate arsenic, they still accumulated relatively high levels in their fronds, approaching 100 mg kg^-1 when grown on a soil dosed with 100 mg kg^-1 arsenic. Arsenic hyperaccumulation was identified as a phenomenon at the extreme range of fern arsenic accumulation. Ferns that exhibit arsenic hyperaccumulation arrived relatively late in terms of fern evolution, as this character is not exhibited by primitive ferns or their allies.

Cadmium hyperaccumulation and genetic differentiation of Thlaspi caerulescens populations

Although the knowledge on heavy metal hyperaccumulation mechanisms is increasing, the genetic basis of cadmium (Cd) hyperaccurnulation remains to be elucidated. Thlaspi caerulescens is an attractive model since Cd accumulation polymorphism observed in this species suggests genetic differences between populations with low versus high Cd hyperaccumulation capacities. In our study, a methodology is proposed to analyse at a regional scale the genetic differentiation of T. caerulescens natural populations in relation to Cd hyperaccumulation capacity while controlling for different environmental, soil, plant parameters and geographic origins of populations. Twenty-two populations were characterised with AFLP markers and cpDNA polymorphism. Over all loci, a partial Mantel test showed no significant genetic structure with regard to the Cd hyperaccumulation capacity. Nevertheless, when comparing the marker variation to a neutral model, seven AFLP fragments (9% of markers) were identified as presenting particularly high genetic differentiation between populations with low and high Cd hyperaccurnulation capacity. Using simulations, the number of outlier loci was showed to be significantly higher than expected at random. These loci presented a genetic structure linked to Cd hyperaccumulation capacity independently of the geography, environment, soil parameters and Zn, Pb, Fe and Cu concentrations in plants. Using a canonical correspondence analysis, we identified three of them as particularly related to the Cd hyperaccumutation capacity. This study demonstrates that populations with low and high hyperaccurnulation capacities can be significantly distinguished based on molecular data. Further investigations with candidate genes and mapped markers may allow identification and characterization of genomic regions linked to factors involved in Cd hyperaccumulation.

Hyperaccumulation of zinc by Noccaea caerulescens results in a cascade of stress responses and changes in the elemental profile

Noccaea caerulescens (J. & C. Presl) F. K. Meyer is a metal hyperaccumulating plant which can accumulate more than 2% zinc (Zn) dry tissue mass in its aerial tissues. At this concentration Zn is toxic to most plants due to inhibition of enzyme function, oxidative damage and mineral deficiencies. In this study the elemental and metabolite profiles of N. caerulescens plants grown in four different Zn concentrations were measured. This revealed broad changes in the metabolite and elemental profiles with the hyperaccumulation of Zn. The Zn treated plants exhibited no typical signs of stress such as chlorosis or reduced biomass, however, a range of metabolic stress responses, such as the modification of galactolipids and the major membrane lipids of plastids, and increases in oxylipins, which are precursors to the signalling molecules jasmonic and abscisic acids, as well as the increased synthesis of glucosinolates, was observed. Increases in particular organic acids and the ubiquitous metal cation chelator nicotianamine were also observed. The small molecule metabolite changes observed, however, did not account for the extreme Zn concentrations in the leaf tissue showing that the increase in nicotianamine production most likely negates Fe deficiency. The elemental analyses also revealed significant changes in other essential micronutrients, in particular, significantly lower Mn concentrations in the high Zn accumulating plants, yet higher Fe concentrations. This comprehensive elemental and metabolite analysis revealed novel metabolite responses to Zn and offers evidence against organic acids as metal-storage ligands in N. caerulescens. © 2014 The Royal Society of Chemistry.

Altered Zn Compartmentation in the Root Symplasm and Stimulated Zn Absorption into the Leaf as Mechanisms Involved in Zn Hyperaccumulation in Thlaspi caerulescens

We investigated Zn compartmentation in the root, Zn transport into the xylem, and Zn absorption into leaf cells in Thlaspi caerulescens, a Zn-hyperaccumulator species, and compared them with those of a related nonaccumulator species, Thlaspi arvense. 65Zn-compartmental analysis conducted with roots of the two species indicated that a significant fraction of symplasmic Zn was stored in the root vacuole of T. arvense, and presumably became unavailable for loading into the xylem and subsequent translocation to the shoot. In T. caerulescens, however, a smaller fraction of the absorbed Zn was stored in the root vacuole and was readily transported back into the cytoplasm. We conclude that in T. caerulescens, Zn absorbed by roots is readily available for loading into the xylem. This is supported by analysis of xylem exudate collected from detopped Thlaspi species seedlings. When seedlings of the two species were grown on either low (1 μm) or high (50 μm) Zn, xylem sap of T. caerulescens contained approximately 5-fold more Zn than that of T. arvense. This increase was not correlated with a stimulated production of any particular organic or amino acid. The capacity of Thlaspi species cells to absorb 65Zn was studied in leaf sections and leaf protoplasts. At low external Zn levels (10 and 100 μm), there was no difference in leaf Zn uptake between the two Thlaspi species. However, at 1 mm Zn2+, 2.2-fold more Zn accumulated in leaf sections of T. caerulescens. These findings indicate that altered tonoplast Zn transport in root cells and stimulated Zn uptake in leaf cells play a role in the dramatic Zn hyperaccumulation expressed in T. caerulescens.

植物对重金属砷和镉胁迫适应的分子机理初探

随着现代工业的发展，重金属污染日趋严重。重金属污染引发的环境和健康问题在许多国家都有报道，我国的重金属污染状况也不容乐观。土壤和水体中的重金属污染可以通过食物链进入人体，对人类健康造成很大的危害，如诱发癌症 和畸胎等。 植物修复是一种利用植物对重金属或有机污染物的超富集能力清除或减低污染的环境生物技术。植物修复的生物学机制的研究为这项技术走向实用化奠定了基础。植物修复近期的进展可能来自于可更有效地富集重金属的植物品种的选择、土壤条件的改善等;但长远看来，植物修复技术的巨大进步将取决于新的可更好地抵抗重金属或降解有机毒物的基因的鉴定和克隆，并通过转基因技术创造一批新的植物品种，如可迅速大量富集重金属的高生物量的用作环境净化的植物，以及可排拒重金属吸收的粮食、蔬菜和水果等作物。 本研究针对砷污染的植物修复机制，以超富集砷的凤尾蕨属植物——蜈蚣草为试材取得了如下进展： 1． 以从砷污染地区采集的蜈蚣草（Pteris vittataL．）为植物材料，利用抑制消减杂交(SSH)分离了经砷诱导处理与其对照间表达有差异的cDNA片段，以期得到与砷富集密切相关的基因。其中筛选到的一个cDNA片段与ABC transporter (ATP-binding cassette transporter)有较高的同源性。通过RACE方法对该基因进行了克隆，并进行了初步的结构和功能分析。结果表明所获得的PvABCTl (Accession No. AY496966)为一全长cDNA，长度为2165 bp，其中开读框架为1791 bp，编码597个氨基酸。该基因所编码的蛋白中含有2个ABC transporter特性结构域，1个ATP-binding cassette和2个ATP/GTP结合位点(P-loop)，没有明显的跨膜区。 2． 对蜈蚣草在砷胁迫下PvABCT1基因的表达模式进行了研究。转录水平分析表明PvABCT1的表达受砷的诱导。进一步通过PvABCTl-GFP融合基因在洋葱细胞中的表达进行亚细胞定位，结果显示该基因可能定位于细胞质中。 3． 为了研究所克隆的PvABCT1基因的功能，本研究构建了PvABCT1的酵母表达载体，把该基因转入因ACR3基因缺失而对砷敏感的酵母突变株。酵母功能互补实验表明PvABCT1不仅不能与ACR3基因功能互补，反而使酵母对砷的敏感性增加，同时酵母细胞中的砷含量较未转化的酵母细胞增加。即在转入PvABCT1后，酵母细胞吸收了更多的砷。这暗示该基因与蜈蚣草中砷的高吸收有关。 针对食品重金属污染问题，本研究探讨了减低蔬菜对重金属吸收的方法及其 作用机理，取得了如下进展： 1．研究了钙离子和镧离子对镉离子胁迫下生菜种子萌发和植株生长的影响，结果表明在种子萌发时外施4 mM CaCI2或0.04 mg/L La(N03)3均可提高生菜对重金属镉的抗性。 2．通过检测0.5 mM CdCl2胁迫下生菜植株中的镉含量以及外施钙离子或镧离子后相应的镉含量，发现4 mM CaCl2可以增加镉胁迫下生菜植株中镉的积累;而0.04 mg/L La(N03)3可以降低镉胁迫下生菜植株中镉的积累。 3．对生菜中植物络合素合酶基因进行了克隆，通过RT-PCR分析以及植物络合素( phytochelatins，PCs)的检测，探讨了外施钙离子或镧离子对镉胁迫下生菜植株中植物络合素合酶基因在转录水平的表达量、植物络合素含量以及镉的积累三者之间的关系。结果表明：4 mM CaCl2可以提高镉胁迫下生菜植株中植物络合素合酶基因在转录水平的表达以及植物络合素的含量，增加镉的积累;而0.04 mg/L La(N03)3虽然同样可以提高植物络合素合酶基因在转录水平的表达以及植物络合素的含量，却能降低镉胁迫下生菜植株中镉的积累。这暗示外施钙离子可以促进用于重金属污染环境修复的植物对重金属的吸收，而外施镧离子可以用于降低叶菜类蔬菜中重金属镉的积累。

砷超富集植物蜈蚣草(Pteris vittata L.)中砷解毒机制的研究

砷是一种具有致癌、致畸、致突变的有毒元素，在地表的含量本来很低。然而，随着现代社会的发展和工业活动的增加导致砷污染日趋严重。土壤和水体中的砷污染可以通过食物链进入人体，对人类的健康造成极大的危害。植物修复是一种利用植物对污染物的超富集能力来清除或减低污染的新型环境生物技术。植物修复的实际应用依赖于超富集植物的发现和超富集机制的阐明，特别是砷解毒过程(砷的吸收、还原和区域化)的研究及相关基因的克隆。砷超富集植物蜈蚣草(Pteris vittata L.)中砷解毒机制的阐明将为砷污染的植物修复及新型工程植物的研发提供理论基础。 本论文以蜈蚣草为试材，针对蜈蚣草的砷解毒机制取得了如下研究进展： 1.以砷超富集植物蜈蚣草为材料，建立了一个适于研究蜈蚣草砷吸收和解毒机制的新系统—愈伤组织悬浮培养体系。首次证明蜈蚣草愈伤组织与其孢子体及配子体一样具有对砷的抗性和砷超富集的能力。 2.以蜈蚣草愈伤组织为材料，通过比较亚砷酸盐、砷酸盐和二甲基胂酸盐对蜈蚣草和拟南芥植物毒性的差异，表明砷的还原可能是蜈蚣草对砷解毒的重要机制之一而砷的甲基化对蜈蚣草的砷解毒作用甚微。 3.以蜈蚣草愈伤组织为材料，通过对砷在蜈蚣草愈伤组织细胞中的亚细胞定位，首次直接证明植物液泡对砷具有非常明显的区隔化作用。暗示区隔化作用在蜈蚣草对砷的解毒过程中发挥着重要的作用。 4.通过测定蜈蚣草愈伤组织对不同化学态的砷处理下抗氧化物质的变化发现酸溶性巯基在蜈蚣草砷解毒中也发挥着重要作用。 5.以蜈蚣草愈伤组织为材料，发现磷和砷的吸收在高浓度范围下（﹥0.2 mM）存在明显的协同效应。对蜈蚣草高亲和磷酸盐转运蛋白基因－PvPHT基因功能的初步分析则表明PvPHT参与了蜈蚣草对磷和砷的吸收过程。

蕨类植物铁芒萁（Dicranopteris dichotoma）体内稀土元素的分布及其光合特性的研究

为了阐明蕨类植物铁芒萁(Dicranopteris dichotoma Bernh.)体内稀土元素的分布及其光合特性，采用电感耦合等离子质谱分析了中国江西省龙南县轻、重稀土矿区和非矿区铁芒萁植物体内的稀土元素含量，并采用透射电子显微镜对其叶片细胞内的稀土元素进行精确定位。还比较系统的研究了自然条件下的铁芒萁与高浓度稀土元素处理条件下的非稀土元素富集植物黄瓜(Cucumis sativus Linn)的光合特性。结果表明： 1、0.5 mmol•L-1 LaCl3处理黄瓜后，可以诱导激发能向PS II分配。1和2 mmol•L-1 LaCl3处理黄瓜后，对黄瓜幼苗抑制作用表现在对其生长率，光合放氧活性和叶绿体完整率的抑制。这是由于LaCl3对黄瓜细胞结构和叶绿体膜结构的破坏所致。其表现为对类囊体膜结构的破坏，而导致PS II光合活性下降，并最终抑制黄瓜生长。 2、铁芒萁可以富集稀土元素，轻、重稀土矿区铁芒萁植物稀土元素的分布规律为叶片>根>土壤>茎>叶柄，非矿区铁芒萁植物稀土元素的分布规律为叶片>根>茎>叶柄。稀土元素在铁芒萁体内的运输和迁移过程中，发生了明显的分异作用，茎、叶柄、叶片中的重稀土相对贫乏，叶片中可以富集高浓度的轻稀土元素。 3、稀土元素可以进入完整的铁芒萁表皮细胞和叶肉细胞中，但多以沉淀的形式聚集在一起。非矿区铁芒萁叶绿体中的稀土元素含量约占其叶片中含量的5％。轻稀土矿区铁芒萁叶绿体中的稀土元素含量约占其叶片中含量的10％。部分稀土元素定位于富含PS II的基粒片层上。 4、铁芒萁富集稀土元素受环境和遗传特性的双重影响，但主要由其自身的生理、生化特性决定。其富集稀土元素的机制是隔离稀土元素在细胞壁、液泡中和分泌结合物质使稀土元素成为沉淀沉积下来，从而避免对光合活性的破坏。 5、与非矿区铁芒萁相比，轻稀土矿区植物叶绿体膜的全链电子传递速率增加了34.9％，PS II的电子传递活性增高了252.9％，PS I的电子传递活性增加了16.8％。轻稀土矿区铁芒萁全链电子传递活性的增加主要来自PS II电子传递活性的大幅提高，这可能与其调节激发能更多向PS II分配，提高PS II反应中心色素蛋白复合体（67.0％）和捕光色素蛋白复合体的含量相关。 6、与非矿区铁芒萁相比，重稀土矿区植物叶绿体膜的全链电子传递速率增加了46.3％，PS II的电子传递活性增高了23.8％，PS I的电子传递活性增加了60.4％。重稀土矿区铁芒萁电子传递活性的提高主要来自PS I电子传递活性的大量增加，这可能与其PS I反应中心蛋白复合体含量的提高（60.0％）有关。 铁芒萁富集并吸收稀土元素主要是由自身的理化特性决定的。它能够将稀土元素以沉淀的形式固定在细胞内部，并通过改变生理代谢来避免高浓度稀土元素对其光合作用的影响。可以在治理稀土元素污染的环保工程中用作植物修复材料。

Heavy metals in plants and phytoremediation - A state-of-the-art report with special reference to literature published in Chinese journals

Goal, Scope and Background. In some cases, soil, water and food are heavily polluted by heavy metals in China. To use plants to remediate heavy metal pollution would be an effective technique in pollution control. The accumulation of heavy metals in plants and the role of plants in removing pollutants should be understood in order to implement phytoremediation, which makes use of plants to extract, transfer and stabilize heavy metals from soil and water. Methods. The information has been compiled from Chinese publications stemming mostly from the last decade, to show the research results on heavy metals in plants and the role of plants in controlling heavy metal pollution, and to provide a general outlook of phytoremediation in China. Related references from scientific journals and university journals are searched and summarized in sections concerning the accumulation of heavy metals in plants, plants for heavy metal purification and phytoremediation techniques. Results and Discussion. Plants can take up heavy metals by their roots, or even via their stems and leaves, and accumulate them in their organs. Plants take up elements selectively. Accumulation and distribution of heavy metals in the plant depends on the plant species, element species, chemical and bioavailiability, redox, pH, cation exchange capacity, dissolved oxygen, temperature and secretion of roots. Plants are employed in the decontamination of heavy metals from polluted water and have demonstrated high performances in treating mineral tailing water and industrial effluents. The purification capacity of heavy metals by plants are affected by several factors, such as the concentration of the heavy metals, species of elements, plant species, exposure duration, temperature and pH. Conclusions. Phytoremediation, which makes use of vegetation to remove, detoxify, or stabilize persistent pollutants, is a green and environmentally-friendly tool for cleaning polluted soil and water. The advantage of high biomass productive and easy disposal makes plants most useful to remediate heavy metals on site. Recommendations and Outlook. Based on knowledge of the heavy metal accumulation in plants, it is possible to select those species of crops and pasturage herbs, which accumulate fewer heavy metals, for food cultivation and fodder for animals; and to select those hyperaccumulation species for extracting heavy metals from soil and water. Studies on the mechanisms and application of hyperaccumulation are necessary in China for developing phytoremediation.

Evidence of various mechanisms of Cd sequestration in the hyperaccumulator Arabidopsis halleri, the non accumulator Arabidopsis lyrata and their progenies by combined synchrotron-based techniques

Arabidopsis halleri is a model plant for Zn and Cd hyperaccumulation. The objective of this study was to determine the relationship between the chemical forms of Cd, its distribution in leaves, and Cd accumulation and tolerance. An interspecific cross was carried out between A. halleri and the non-tolerant and non-hyperaccumulating relative A. lyrata providing progenies segregating for Cd tolerance and accumulation. Cd speciation and distribution were investigated using X-ray absorption spectroscopy and microfocused X-ray fluorescence. In A. lyrata and non-tolerant progenies, Cd was coordinated by S atoms only or with a small contribution of O groups. Interestingly, the proportion of O ligands increased in A. halleri and tolerant progenies, and they were predominant in most of them, while S ligands were still present. Therefore, the binding of Cd with O ligands was associated with Cd tolerance. In A. halleri, Cd was mainly located in the xylem, phloem, and mesophyll tissue, suggesting a reallocation process for Cd within the plant. The distribution of the metal at the cell level was further discussed. In A. lyrata, the vascular bundles were also Cd enriched, but the epidermis was richer in Cd as compared with the mesophyll. Cd was identified in trichomes of both species. This work demonstrated that both Cd speciation and localization were related to the tolerance character of the plant.

Arsenic uptake and metabolism in plants

Arsenic (As) is an element that is nonessential for and toxic to plants. Arsenic contamination in the environment occurs in many regions, and, depending on environmental factors, its accumulation in food crops may pose a health risk to humans.Recent progress in understanding the mechanisms of As uptake and metabolism in plants is reviewed here. Arsenate is taken up by phosphate transporters. A number of the aquaporin nodulin26-like intrinsic proteins (NIPs) are able to transport arsenite,the predominant form of As in reducing environments. In rice (Oryza sativa), arsenite uptake shares the highly efficient silicon (Si) pathway of entry to root cells and efflux towards the xylem. In root cells arsenate is rapidly reduced to arsenite, which is effluxed to the external medium, complexed by thiol peptides or translocated to shoots. One type of arsenate reductase has been identified, but its in planta functions remain to be investigated. Some fern species in the Pteridaceae family are able to hyperaccumulate As in above-ground tissues. Hyperaccumulation appears to involve enhanced arsenate uptake, decreased arsenite-thiol complexation and arsenite efflux to the external medium, greatly enhanced xylem translocation of arsenite, and vacuolar sequestration of arsenite in fronds. Current knowledge gaps and future research directions are also identified.

Mechanisms of plant resistance to metal and metalloid ions and potential biotechnological applications

Metal and metalloid resistances in plant species and genotypes/accessions are becoming increasingly better understood at the molecular and physiological level. Much of the recent focus into metal resistances has been on hyperaccumulators as these are excellent systems to study resistances due to their very abnormal metal(loid) physiology and because of their biotechnological potential. Advances into the mechanistic basis of metal(loid) resistances have been made through the investigation of metal(loid) transporters, the construction of mutants with altered metal(loid) transport and metabolism, a better understanding of the genetic basis of resistance and hyperaccumulation and investigations into the role of metal(loid) ion chelators. This review highlights these recent advances. © Springer 2005.