镉在两种菊芋品种中的吸收与转移特性研究

Jerusalem artichoke(Helianthus tuberosus L.) not just can be used for bioethanol production but may be potentially used in phytoremediation for the removal of heavy metal pollutants.Two Jerusalem artichoke cultivars,N2 and N5,were subjected to six cadmium(Cd) concentrations(0,5,25,50,100 and 200 mg L1) to investigate Cd tolerance and accumulation.After 21 days of growth,the effects of Cd on growth,chlorophyll content,net photosynthetic rate,intercellular CO2 concentration and malondialdehyde content were evaluated.Most growth parameters were reduced under Cd stress.The two Jerusalem artichoke cultivars had relatively high Cd tolerance and accumulation capacity(> 100 mg kg1),with N5 being more tolerant and having higher Cd accumulation than N2.Roots accumulated more Cd than stems and leaves.The bioconcentration factors(far higher than 1) and translocation factors(lower than 1) decreased with an increase in Cd applied.The results suggested that Jerusalem artichoke could be grown at relatively high Cd loads,and N5 could be an excellent candidate for phytoremediation of Cd-contaminated soils.     

植物对镉毒害的形态和生理响应研究进展

Cadmium (Cd) contamination has posed an increasing challenge to environmental quality and food security.In recent years,phytoremediation has been particularly scrutinized because it is cost-effective and environmentally friendly,especially the use of metal-hyperaccumulating plants to extract or mine heavy metals from polluted soils.Under Cd stress,responses of hyperaccumulator and non-hyperaccumulator plants differ in morphological responses and physiological processes such as photosynthesis and respiration,uptake,transport,and assimilation of minerals and nitrogen,and water uptake and transport,which contribute to their ability to accumulate and detoxify Cd.This review aims to provide a brief overview of the recent progresses in the differential responses of hyperaccumulator and non-accumulator plants to Cd toxicity in terms of growth and physiological processes.Such information might be useful in developing phytoremediation technology for contaminated soils.     

锌镉超富集植物滇苦菜中碳酸酐酶对镉的响应

A number of higher plants are able to hyperaccumulate cadmium(Cd). However, it is unknown whether cadmium(Cd) plays a biological functional role in the carbonic anhydrase(CA) of hyperaccumulators. A hydroponic experiment was conducted to explore the potentially physiological function of Cd in CA and the accumulation and tolerance of Cd in the Zn/Cd hyperaccumulator Picris divaricata Vant. P. divaricata was exposed to nutrient solutions with six Cd concentrations(0, 5, 10, 25, 50 and 75 μmol L~(-1)). After 12 d, plants were harvested for the analysis of plant biomass, Cd concentration and CA activity. The Cd concentrations in plant increased with the increasing Cd in nutrient solution, reaching 640 and 3 100 mg kg~(-1) in shoot and root, respectively, at the 75 μmol L~(-1) Cd treatment. Meanwhile, plant growth was enhanced by the Cd treatments at 5–25 μmol L~(-1), but it was significantly inhibited when the plants were exposed to solutions with higher Cd concerntrations(50 and 75 μmol L~(-1)). Exposure to Cd significantly increased the CA activity in P. divaricata, which reached a maximum value of 21.27 U mg~(-1) proteins at the 25 μmol L~(-1)Cd treatment, and the CA activity and shoot Cd concentration were positively correlated at solutions Cd of ≤ 25 μmol L~(-1). Moreover, two protein bands appeared on the denatured gel electrophoresis of purified CA, indicating that P. divaricata may have CA isomers with their respective molecular weights at around 60 and 55 k Da, at least one of which is Cd-bound. In addition, trace amounts of Cd in purified CA significantly increased with the supplied Cd concentration in nutrient solution(5–25 μmol L~(-1)). The results suggested that Cd may play a biological role by enhancing the activities and forming the active Cd-specific CA in the hyperaccumulator P. divaricata.     

中国东部太湖地区酸性水稻土团聚体上铜的专性和非专性吸附动力学研究

The Taihu Lake region in East China has become prone to soil acidification, which changes heavy metals such as copper(Cu) in soil into water-soluble species and increases the mobility and contamination risks of heavy metals in the biological environment. In this study, the kinetics of Cu2+sorption by the bulk soil and the aggregate size fractions of an acidic paddy soil collected from the Taihu Lake region, the effects of temperature on Cu2+sorption, and the p H changes of the solution were investigated by static sorption and magnetic stirring. The aggregate size fractions were prepared by low-energy ultrasonic dispersing and freeze-drying. The total sorption amounts of the bulk soil and the aggregate size fractions for Cu2+followed a descending order of clay > coarse sand > bulk soil > silt> sand, corresponding to those of organic matter content, free iron oxide content, free aluminum oxide content, and cation exchange capacity. The kinetic sorption curves of Cu2+by the bulk soil and the aggregates, which were divided into two stages(rapid and slow sequentially), were well fitted by the first-order equation, the diffusion equation, and the Elovich equation, showing significant correlations(P < 0.05). Specific and non-specific sorption dominated in the fast and slow stages, respectively, and the former was predominant throughout the sorption process. The specific sorption accelerated and the non-specific sorption decelerated with rising temperature. The p H of the solution decreased significantly during the specific sorption and remained unchanged or increased slightly during the non-specific sorption. When the specific sorption terminated, the p H of the solution was minimized nearly simultaneously.The sorption progress of Cu2+by the bulk soil significantly preceded that by the aggregates. Therefore, heavy metal contamination may be another factor reducing soil p H and metal sorption forms should be taken into consideration in studies of mitigating soil heavy metal pollution or determining environmental capacity of heavy metal in soil.     

深色有隔内生真菌柱孢顶囊壳对玉米幼苗生长、光合作用及耐铅能力的影响

Dark septate endophytic (DSE) fungi are ubiquitous and cosmopolitan,and occur widely in association with plants in heavy metal stress environment.However,little is known about the effect of inoculation with DSE fungi on the host plant under heavy metal stress.In this study,Gaeumannomyces cylindrosporus,which was isolated from Pb-Zn mine tailings in China and had been proven to have high Pb tolerance,was inoculated onto the roots of maize (Zea mays L.) seedlings to study the effect of DSE on plant growth,photosynthesis,and the translocation and accumulation of Pb in plant under stress of different Pb concentrations.The growth indicators (height,basal diameter,root length,and biomass) of maize were detected.Chlorophyll content,photosynthetic characteristics (net photosynthetic rate,transpiration rate,stomatal conductance,and intercellular CO2 concentration),and chlorophyll fluorescence parameters in leaves of the inoculated and non-inoculated maize were also determined.Inoculation with G.cylindrosporus significantly increased height,basal diameter,root length,and biomass of maize seedlings under Pb stress.Colonization of G.cylindrosporus improved the efficiency of photosynthesis and altered the translocation and accumulation of Pb in the plants.Although inoculation with G.cylindrosporus increased Pb accumulation in host plants in comparison to non-inoculated plants,the translocation factor of Pb in plant body was significantly decreased.The results indicated that Pb was accumulated mainly in the root system of maize and the phytotoxicity of Pb to the aerial part of the plant was alleviated.The improvement of efficiency of photosynthesis and the decrease of translocation factor of Pb,caused by DSE fungal colonization,were efficient strategies to improve Pb tolerance of host plants.     

镉对龙葵幼苗生长和生理指标的影响

采用营养液培养法研究了镉胁迫条件下龙葵幼苗生长、生理响应及镉积累特性。结果表明,镉胁迫下,龙葵幼苗生长受到一定程度的抑制,并且具有浓度效应和时间效应。镉胁迫还导致龙葵叶片色素含量下降。叶绿素a、b和类胡萝卜素平均含量在高浓度镉（150μmol·L^-1）处理条件下分别较对照降低55．5％、63．9％和43．3％。低浓度镉（25μmol·L^-1）处理15d内显著促进龙葵幼苗根系活力,平均根系活力较对照上升10．4％,而高浓度镉处理下,根系活力呈现先升后降的趋势,镉处理10d之后达到峰值;随着镉浓度的升高和胁迫时间的延长,龙葵幼苗叶片相对电导率、丙二醛（MDA）含量和渗透调节物质均呈现显著上升趋势。相对于对照植株,低浓度镉处理下龙葵叶片平均相对电导率、MDA含量、可溶性糖和脯氨酸含量上升17．7％、117．7％、5．6％和95．3％,而高浓度镉处理下上升幅度更大,分别为39．0％、194．6％、56．3％和758．0％。从积累部位来看,镉主要积累在龙葵幼苗地上部,镉含量由高到低依次为叶片〉茎〉根系,高浓度镉胁迫20d之后根茎叶镉含量为5d时的1．73、1．49和1．40倍,分别为1287．25、1718．14和2385．27μg·g^-1DW。     

镉胁迫对两个水稻品种幼苗光合参数、可溶性糖和植株生长的影响

以较耐镉(武育粳3号,WYJ)和镉敏感(汕优63,SY63)的2个不同耐性水稻品种为材料,采用溶液培养试验,研究了镉处理(Cd.1.0和5.0mol/L)对水稻幼苗光合作用、可溶性糖和生长的影响。结果表明,镉胁迫下,水稻幼苗的光合作用显著地受到抑制。与不加镉的对照相比,随镉水平的提高水稻幼苗净光合速率(Pn)、气孔导度(Gs)、蒸腾速率(Tr)、气孔限制值(Ls)逐步下降,尤其是在Cd.5.0mol/L处理下的植株,下降幅度武育粳3号显著小于汕优63。蒸腾效率(Te)也随镉浓度的增加而降低,但变化与净光合速率等不同,武育粳3号的下降速率要大于汕优63的。加镉处理使2个水稻品种幼苗叶片可溶性糖含量均显著升高,而叶绿素含量仅汕优63在Cd.5.0mol/L处理下与对照差异显著。加镉处理使汕优63根系生长(根长)显著受到抑制,而株高仅在Cd.5.0mol/L时显著降低。武育粳3号生长与对照差异不显著。本研究结果表明,随着镉处理水平的提高,镉对水稻幼苗的毒害作用增加,但是水稻对镉毒害的响应存在明显的基因型差异。     

两种微生物菌剂对小麦幼苗生长和磷吸收机理的影响研究

采用盆栽试验,研究了施用不同形态磷肥的土壤上接种SP11(细菌)、T50(真菌)后对小麦幼苗生长和磷吸收利用的影响.结果表明:SP11(细菌)可增加小麦根际磷酸酶活性和促进有机酸分泌,降低土壤pH,显著促进小麦生长,提高小麦对磷的吸收;T50(真菌)虽可增加小麦根际磷酸酶活性,但在整个试验中提高小麦对磷的利用率和促进小麦生长等作用不稳定,故SP11细菌接种剂可作为生长促进剂推广应用.     

伴矿景天和鹅掌柴间作系统中根系相互作用对植物生长和镉锌吸收的影响

为明确不同物种根系间的相互作用对植物生长和重金属元素吸收的影响,以Cd、Zn超积累植物伴矿景天与花卉植物鹅掌柴为材料,研究二者根系相互作用及对植物生长和Cd、Zn的影响。结果发现,二者根系具有相互抑制生长的作用。单作条件下伴矿景天的Cd、Zn吸收量最高,分别达0.812、19.6 mg/盆;较单作相比,无分隔间作条件下伴矿景天对土壤Cd、Zn吸收降低分别达30.0%和30.6%。两种植物根系改变了土壤养分性质,对土壤钾和磷的利用分别具有竞争和互补作用,但其有效态含量并未降低到亏缺水平,养分竞争可能不是两种植物根系相互作用的主要因素。水培试验表明鹅掌柴根系分泌物对伴矿景天的生长和Cd吸收具有抑制作用。     

镉胁迫对不同小麦品种幼苗生长以及Cd~(2+)、Zn~(2+)、Mn~(2+)吸收和积累的影响

以洛旱6号、豫麦25、豫麦18、豫农949、新麦21及许农5号为试验材料,通过营养液培养法,研究了镉胁迫对其幼苗生物量积累以及Cd2+、Zn2+与Mn2+吸收的影响。结果表明,与正常生长小麦相比,低Cd2+(≤30μmol/L)浓度下,除许农5号地上部生物量有所下降外,其余品种的地上部和地下部生物量均呈上升趋势。中、高Cd2+(≥60μmol/L)浓度下,所有品种的生物量呈下降趋势,所有小麦品种体内Cd2+的含量均随着Cd2+处理浓度的增加而不断增加,而且,根系内Cd2+的含量均明显高于地上部。随着Cd2+处理浓度的增加,所有小麦品种地上部Zn2+的含量均不断增加,地下部Zn2+含量的变化品种间存在差异。地上、地下部Mn2+的含量则随处理浓度增加而不断降低。     

Cadmium found in peanut (Arachis hypogaea L.) kernels mainly originates from root uptake rather than shell absorption from soil

Roots and shells are two potential organs through which peanut plants absorb cadium (Cd) from soils; however, the relative contributions of the two uptake pathways (root uptake and shell absorption) to kernel Cd accumulation and their translocation characteristics are poorly understood. In this study, the relative contributions of the two pathways to Cd accumulation in two peanut cultivars, Xianghua2008 (XH) and Yueyou43 (YY), were accurately assessed by labeling rooting and podding zone soils with ¹¹³Cd and ¹¹³Cd isotopes (0.3 mg kg^-1 dry soil), respectively, in a split-pot design. The results showed that approximately 96% of the Cd accumulated in the peanut kernels was derived from root uptake, while only 4% originated from shell absorption. Only 1% of the Cd accumulated in whole peanut plants was attributed to shell absorption, of which 41%–44% was retained in shells and 56%–59% was translocated to kernels. In contrast, the Cd absorbed by roots was efficiently translocated into all plant organs, of which 80%–84% was distributed in shoots. Although YY accumulated 1.3 times more Cd in whole plants than XH, the relative contributions of the two pathways to Cd accumulation in each plant organ were barely affected by peanut cultivars. Due to the strong retention effect of shells, shell-derived Cd was approximately 2 times higher than root-derived Cd in shells. These results would improve the understanding of Cd accumulation processes in peanut plants, revealing that the root uptake pathway contributes predominantly to the Cd concentration in peanut kernels, based on which strategies and technology for the reduction of Cd in peanut plants could be designed and developed.     

Rice (Oryza sativa L.) seedlings enriched with zinc or manganese: Their impacts on cadmium accumulation and expression of related genes

Cadmium (Cd) contamination in paddy soils means that the rice produced there may be unsafe for human consumption. A hydroponic study was conducted to enrich rice seedlings with zinc (Zn) or manganese (Mn), and the uptake and transport characteristics of Cd in these Zn- and Mn-rich seedlings were subsequently investigated using a greenhouse pot trial. The results showed that hydroponic cultivation in 10–50 μmol L^-1 Zn (ZnSO₄·7H₂O) or 50–250 μmol L^-1 Mn (MnSO₄·H₂O) for 30 d had no significant impact on rice growth, while the accumulation of Zn and Mn was 7.31–18.5 and 25.4–47.7 times higher, respectively, than in the control (no Zn or Mn addition). The accumulation of Cd in the Zn- and Mn-rich rice plants was 26.3%–38.6% and 34.4%–44.5% lower than that in the control, respectively, and the translocation factors of Cd from roots to shoots also decreased by 23.3%–41.3% and 25.3%–37.0%, respectively, after transplanting to Cd-contaminated soils. Furthermore, the relative expression levels of OsIRT1 (Oryza sativa iron-regulated transporter 1) were downregulated by 40.1%–59.3% and 16.0%–25.9%, respectively, in the Zn- and Mn-rich seedling roots. This downregulation may indicate a possible mechanism contributing to the reductions in Cd absorption. Field experiments confirmed that the Zn- and Mn-rich seedlings produced brown rice (unpolished rice grains) with significantly decreased concentrations of Cd (34.2%–44.4%). This study provides an innovative method for reducing the food safety risks from rice grown on slightly to moderately Cd-contaminated paddy soils.     

An effective planting model to decrease cadmium accumulation in rice grains and plants: Intercropping rice with wetland plants

Cadmium (Cd) pollution affects plant growth and poses a serious threat to food safety and human health.Cadmium-contaminated rice is assumed to be the main source of Cd exposure to humans,with grave health risks.Phytoremediation is an efficient,cost-effective,and eco-friendly approach to minimize Cd accumulation in rice.However,research on the effect of rice intercropping with wetland plants that exhibit great capacity for phytoremediation in decreasing Cd concentrations in paddies is limited.A p...     

堆肥缓解土壤镉的植物毒性: 对白菜生长的影响

The growth performance of pakchoi (Brassica chinensis L.) in relation to soil cadmium (Cd) fractionations was investigated to evaluate the remediating effect of poultry manure compost on Cd-contaminated soil. A yellow-brown soil (Alfisol) treated with various levels of Cd (0–50 mg Cd kg-1 soil) was amended with increasing amounts of compost from 0 to 120 g kg-1 . Compost application transformed 47.8%–69.8% of soluble/exchangeable Cd to the organic-bound fraction, and consequently decreased Cd uptake of pakchoi by 56.2%–62.5% as compared with unamended soil. Alleviation of Cd bioavailability by compost was attributed primarily to the increase of soil pH and complexation of Cd by organic matter including dissolved organic matter. In general, the improvement of pakchoi performance was more pronounced in higher Cd-contaminated soil. Addition of large amount of compost also favored the anti-oxidative capability of pakchoi against Cd toxicity. This low cost remediation method seems to be very effective in the restoration of Cd-contaminated soils.     

水分管理和施用石灰对水稻镉吸收与运移的影响

通过田间试验,研究了间歇灌溉和全生育期淹水2种水分管理结合水稻分蘖期施用石灰对不同水稻生育期的土壤和水稻各组织中Cd分布与运移的影响。研究结果表明,全生育淹水和施用石灰均能升高土壤p H值,降低土壤中有效态Cd含量;施用石灰能降低土壤中酸可提取态Cd所占比例而残渣态所占比例增加。在全生育期淹水条件下施用石灰有利于改善土壤性状并提高土壤中Fe质量百分含量。与不施用石灰相比,在间歇灌溉条件下,施用石灰处理的糙米中Cd质量分数从0.86 mg/kg降低到0.56 mg/kg,而在全生育期淹水条件下,施用石灰处理的糙米中Cd质量分数从0.77 mg/kg降低到0.34 mg/kg;无论间歇灌溉还是全淹水处理条件下,施用石灰均增加了水稻总生物量。施用石灰后,在灌浆期,水稻茎叶中Cd的富集系数显著降低(P0.05);在成熟期,根和稻米中Cd的富集系数显著降低(P0.05);在全生育期淹水条件下,成熟期水稻根到茎叶转运系数和茎叶到米中转运系数均显著降低(P0.05)。水稻糙米中Cd含量与土壤中有效态Cd含量、水稻地上部Cd累积量呈显著正相关,与土壤p H值呈显著负相关。上述研究结果表明,施用石灰能够显著降低稻田土壤中Cd的生物有效性;采用全生育期淹水结合在分蘖期施用石灰是降低稻米中Cd含量有效措施且不会导致水稻减产。     

接种耐铬细菌菌株对二月兰中铬积累及其生长状况的影响

Beneficial interactions between microorganisms and plants, particularly in the rhizosphere, are a research area of global interest. Four cadmium （Cd）-tolerant bacterial strains were isolated from heavy metal-contaminated sludge and their effects on Cd mobility in soil and the root elongation and Cd accumulation of Orychophragmus violaceus were explored to identify the capability of metal- resistant rhizobacteria for promoting the growth of O. violaceus roots on Cd-contaminated soils. The isolated strains, namely, Bacillus subtilis, B. cereus, B. megaterium, and Pseudomonas aeruginosa, significantly enhanced the plant Cd accumulation. The Cd concentrations in the roots and shoots were increased by up to 2.29- and 2.86-fold, respectively, by inoculation of B. megaterium, as compared with the uninoculated control. The bacterial strains displayed different effects on the shoot biomass. Compared with the uninoculated plants, the shoot biomass of the inoculated plants was slightly increased by B. megaterium and significantly decreased by the other strains. B. megaterium was identified as the best candidate for enhancing Cd accumulation in O. violaceus. Thus, this study provides novel insight into the development of plant-microbe systems for phytoremediation.     

Intercropping of Sonchus asper and Vicia faba affects plant cadmium accumulation and root responses

The cadmium(Cd)pollution of farmland soil is serious in the world.The present study investigated the effects of intercropping Vicia faba and the hyperaccumulator Sonchus asper on the Cd accumulation and root responses(morphology and secreted organic acids)of plants grown on soil from a mining area in Yunnan Province,China,under different Cd stress levels(0,50,100,and 200 mg kg^-1).Intercropping increased the biomass of both S.asper and V.faba,as well as the Cd accumulation and Cd trans...