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1.
日本Yamagata大学的科学家T.Wngatsuma及其同事描述了一种从铝-耐受和铝-敏感植物细胞混合物中收集耐铝植物细胞的新技术。基于以前发现耐铝品种的原生质体比铝-敏感品种的原生质体质膜表面的负电荷少,Wagatsutma小组用新准备的带正电的二氧化硅小珠与来源于水稻(Al-耐受),玉米(中等Al-耐受)或豌豆(Al-敏感)根细胞的纯化原生质体混合,然后以一个Ficoll不连续梯度高心混合物。他们从离心管底部级分得到来自铝-耐受植物(水稻)的原生质体,从上部级分得到来自铝-敏感植物(豌豆)…  相似文献   

2.
酸性土壤上铝毒是限制作物产量的一个重要障碍因子。具有螯合能力的有机酸在植物铝的外部排斥机制和内部耐受机制均具有重要作用。在铝的外部排斥解毒过程中,植物通过根系分泌有机酸进入根际,如柠檬酸、草酸、苹果酸等与铝形成稳定的复合体,阻止铝进入共质体,从而达到植物体外解除铝毒害效应的目的,且分泌的有机酸对铝的胁迫诱导表现出高度的专一性,分泌的关键点位于根尖。不同的物种间分泌的有机酸种类、分泌的模式及生理机理存在差异。在铝积累型植物的内部解毒过程中,有机酸与铝形成稳定的化合物,降低植物体内铝离子的生理活性,从而降低细胞内铝离子的毒害效应,如绣球花中铝与柠檬酸形成1:1的复合体,荞麦内铝与草酸形成1:3的复合体。本文就有机酸在植物忍耐和积累铝中的作用及生理机制作一简要综述。  相似文献   

3.
植物铝胁迫响应基因的研究进展   总被引:1,自引:0,他引:1  
铝毒是酸性土壤中植物生长和作物生产的主要限制因子.近年来的很多研究应用差异显示PCR、抑制差减cDNA文库和DNA微正列等技术,在一些铝耐受型和敏感型植物中鉴定了很多铝胁迫响应基因.本研究通过参阅国内外有关报道和结合本实验室的研究成果,从铝诱导的通道蛋白、代谢相关、胁迫和细胞死亡以及信号转导相关基因4个方面的研究进展进行了综述.  相似文献   

4.
有机酸在植物解铝毒中的作用及生理机制   总被引:11,自引:0,他引:11  
酸性土壤上铝毒是限制作物产量的一个重要障碍因子,具有螯合能力的有机酸在植物铝的外部排斥机制和内部耐受机制均具有重要作用,在铝的外部排斥解毒过程中,植物通过根系分泌有机酸进入根际,如柠檬酸,草酸,苹果酸等与铝形成稳定的复合体,阻止铝进入共质体,从而达到植物体外解除铝毒害效应的目的,且分泌的有机酸对铝的胁迫诱导表现出高度的专一性,分泌的关键点位于根尖,不同的物种间分泌的有机酸种类,分泌的模式及生理机理存在差异,在铝积累型植物的内部解毒过程中,有机酸与铝形成稳定的化合物,降低植物体内铝离子的生理活性,从而降低细胞内铝离子的毒害效应,如绣球花中铝与柠檬酸形成1:1的复合体,荞麦内铝与草酸形成1:3的复合体,本文就有机酸在植物忍耐和积累铝中的作用及生理机制作一简要综述。  相似文献   

5.
铝超积累植物和铝排斥植物吸收和累积铝的机理   总被引:14,自引:0,他引:14  
谢正苗  黄铭洪  叶志鸿 《生态学报》2002,22(10):1653-1659
研究了香港茶园天然生态系统中铝超积累植物和铝排斥植物包括茶树(Camellia sinensis L.)、多花野牡丹(Melastoma affine L.)、假苹婆(Sterculia lanceolata L.)、大罗伞紫金牛(Ardisia crenata L.)、相思树(Acacia formosa L.)和红楠(Machilus thunbergii Machilus thunbergii L.)对铝吸收和累积的机理。6种植物新鲜根和茎的pH值变化范围为3-6,不同部位全铝含量变化幅度为13-12810mg/kg(干重,下同)。新鲜植物组织的pH值是控制植物对铝吸收、转运和累积的最重要的因素。植物中的铝浓度随其pH值降低而显著增加。供试6种植物可分为两组:一组是铝排斥植物,其pH值大约6,叶中含铝量范围为17-151mg/kg,包括假苹婆、大罗伞紫金牛、相思树和红楠;另一组是铝超积累植物,其pH值为3和4.5,叶中含铝量范围为7820-12810mg/kg,包括茶树和多花野牡丹。铝超积累植物新鲜根中水溶性铝与全铝的比例(0.11-0.88)高于铝排斥植物根中的比例(0.04-0.07)。相同趋势可见于茎和叶中,特别在多花野牡丹茎叶中。结果表明:新鲜根、茎和叶中水溶性铝与全铝的比例高可以增加植物从土壤-植物系统中铝的迁移速率,导致较高的铝吸收累积。根际和非根际土壤的pH值有显著差异。通常,象多花野牡丹一样的铝超积累植物,其组织pH值低,降低了根限pH,使土壤中铝更容易吸收。铝排斥植物增根际土壤的pH值,以避免根对铝的高量吸收。  相似文献   

6.
酸铝胁迫是限制植物正常生长发育的重要非生物胁迫因子,严重制约了我国酸性土壤地区的农业生产水平。植物抵御酸铝胁迫的形式复杂多样,如分泌有机酸、提高根际pH、分泌黏液、细胞壁对Al3+的固定、有机酸对细胞溶质中Al3+的螯合与液泡区隔化等。现有研究多集中于常规生理特征分析,缺乏深入的分子生物学解析。基于此,本文对国内外植物适应酸铝胁迫机理的相关研究进行了归纳和总结,从酸铝胁迫对植物生长与生理代谢的影响、植物适应酸铝胁迫最主要的两种生理机制(Al排除机制、Al耐受机制)以及分子水平上调控相关耐铝基因进行了综述。最后针对现有研究的不足提出了展望,以期为深入揭示植物适应酸铝胁迫的机理以及挖掘适于酸土生长的优质作物资源提供理论依据。  相似文献   

7.
植物耐铝的生理机制   总被引:8,自引:0,他引:8  
就植物本身的解除铝毒生理机制、铝毒与膜整合阴离子通道、铝毒与有机酸代谢相关酶、转基因与植物耐铝性的提高、耐铝基因的QTL以及参与铝毒响应的信号转导机制的研究进展作介绍。  相似文献   

8.
本文简单概述了目前植物铝毒害及遗传育种方面的研究进展。Al3+可以通过与细胞骨架的作用,影响根的正常生理功能和形态建成。 植物可以通过根尖分泌有机酸或磷酸等将离子态的铝变成螯合态的铝,通过吸收H+提高根尖周围的pH,将Al3+变成难溶性的 Al(OH)3或磷酸铝从而解除铝毒害, 也可以通过在细胞内与Al3+形成无毒害的复合结构从而解除铝毒害。国外通过基因工程和突变体筛选已经获得了一批耐铝的植物材料,国内一些研究者通过突变体筛选也获得了一些耐铝的植物材料。 对植物耐铝性的遗传研究表明, 植物的耐铝性既可以是受单基因控制的,也可以是受多基因控制的。  相似文献   

9.
植物铝毒害及遗传育种研究进展   总被引:38,自引:0,他引:38  
本文简单概述了目前植物铝毒害及遗传育方面的研究进展,Al^3 可以通过与细胞骨架的作用,影响根的正常生理功能和形态建成,植物可以通过根尖分泌有机酸或磷酸等将离子态的为成螯合态的铝,通过吸收H^ 提高根尖周围的pH,将Al^3 变成难溶性的Al(OH)3或磷酸铝从而解 除铝毒害,也可以通过在细胞内与Al^3 形成无毒害的复合结构从而解除铝毒害,国外通过基因工程和突变体筛选已经获得了一批耐铝的植物材料,国内一些研究者通过变体筛选也获得了一些耐铝的植物材料,对植物耐铝性的遗传研究表明,植物的耐铝性既可以是受单基因控制的,也可以是受多基因控制的。  相似文献   

10.
微生物铝毒害和耐铝毒机制研究进展   总被引:1,自引:0,他引:1  
在酸性土壤中,铝毒是限制农作物生产的关键问题之一,铝同样对微生物产生毒害作用。研究微生物的铝毒害和耐铝毒机制可以为植物耐铝毒机制的研究提供一种新视角。目前的研究表明,铝作用于微生物细胞的细胞壁、细胞膜、细胞核和细胞器,影响微生物的物质和能量代谢,抑制微生物的生长和发育。针对这些毒害作用,铝毒耐受微生物通过多途径全方位的机制适应外界的铝毒环境。该文结合作者的研究工作,综述了微生物的铝毒害和耐铝毒机制。  相似文献   

11.
Three plant cDNA libraries were expressed in yeast (Saccharomyces cerevisiae) and screened on agar plates containing toxic concentrations of aluminum. Nine cDNAs were isolated that enhanced the aluminum tolerance of yeast. These cDNAs were constitutively expressed in Arabidopsis (Arabidopsis thaliana) and one cDNA from the roots of Stylosanthes hamata, designated S851, conferred greater aluminum tolerance to the transgenic seedlings. The protein predicted to be encoded by S851 showed an equally high similarity to Delta6 fatty acyl lipid desaturases and Delta8 sphingolipid desaturases. We expressed other known Delta6 desaturase and Delta8 desaturase genes in yeast and showed that a Delta6 fatty acyl desaturase from Echium plantagineum did not confer aluminum tolerance, whereas a Delta8 sphingobase desaturase from Arabidopsis did confer aluminum tolerance. Analysis of the fatty acids and sphingobases of the transgenic yeast and plant cells demonstrated that S851 encodes a Delta8 sphingobase desaturase, which leads to the accumulation of 8(Z/E)-C(18)-phytosphingenine and 8(Z/E)-C(20)-phytopshingenine in yeast and to the accumulation of 8(Z/E)-C(18)-phytosphingenine in the leaves and roots of Arabidopsis plants. The newly formed 8(Z/E)-C(18)-phytosphingenine in transgenic yeast accounted for 3 mol% of the total sphingobases with a 8(Z):8(E)-isomer ratio of approximately 4:1. The accumulation of 8(Z)-C(18)-phytosphingenine in transgenic Arabidopsis shifted the ratio of the 8(Z):8(E) isomers from 1:4 in wild-type plants to 1:1 in transgenic plants. These results indicate that S851 encodes the first Delta8 sphingolipid desaturase to be identified in higher plants with a preference for the 8(Z)-isomer. They further demonstrate that changes in the sphingolipid composition of cell membranes can protect plants from aluminum stress.  相似文献   

12.
Aluminum is one of the most important heavy metals inducing stress during plant growth and development. In this study, transgenic rice (Oryza sativa L., cv. Kitaake) plants expressing the maize C4PEPC and PPDK genes were evaluated for aluminum tolerance. A 4.3 and 19.1 folds increase of PPDK and PEPC activities in transgenic rice produced increases in root exudation of oxalate, malate, and citrate (1.20, 1.41, and 1.65 times, respectively) compared to untransformed (WT) plants. Transgenic rice had enhanced aluminum tolerance compared to WT based on chlorophyll fluorescence and chlorophyll levels. Transgenic plants under aluminum stress also had decreased lipid membrane oxidative damage and higher levels of ROS-scavenging enzyme activity. The PEPC and PPDK genes play an important role in aluminum stress tolerance by increasing the effluxes of organic acids.  相似文献   

13.
Molecular physiology of aluminum toxicity and tolerance in plants   总被引:2,自引:0,他引:2  
Aluminum being the third most abundant metal in the earth’s crust poses a serious threat to crop productivity in acid soils, which comprise almost half of the arable land. This review travels across time and updates research done on aluminum stress in plants. In its phytotoxic forms, aluminum affects root growth by acting in the root apical zone, resulting in growth inhibition in a very short time at micromolar concentrations. The mechanisms of aluminum toxicity in plants may proceed by growth inhibition, callose accumulation, cytoskeletal distortion, disturbance of plasma membrane surface charge, and H+-ATPase activity, lipid peroxidation of membranes, production of reactive oxygen species in cytosol and mitochondria, respiratory dysfunction, opening of mitochondrial permeability transition pores, collapsing of inner mitochondrial membrane potential, activation of mitochondrial protease, and induction of nuclear apoptosis, resulting ultimately in programmed cell death. In contrast, the mechanism of tolerance involves the exudation of organic acid anions, complexation of aluminum with organic acids, and subsequent detoxification. Many oxidative stress genes and other metabolically important genes have also been found to be induced under aluminum stress and overexpression analyses have also shown some plants to develop some degree of tolerance. In the future, researchers in the area of aluminum research should investigate more basic mechanisms of aluminum toxicity and discover and study more aluminum-responsive genes that confer resistance against this toxic metal, to ensure food security for ever-increasing human populations in the future.  相似文献   

14.
Rigin BV  Iakovleva OV 《Genetika》2006,42(3):385-390
The genetic control of high tolerance of toxic aluminum ions in barley Hordeum vulgare L. has been studied. Cultivar Faust I (c-24612) and accession 9736 from Karelia have been compared with aluminum-sensitive cv. Colsess IV (accession c-24626). Analysis of F1, F2BC1, F3, and F4 progenies has shown that the development of roots of cv. Faust I in water medium with aluminum ions is determined by one (AlpF1) or two (AlpF1, AlpF2) genes. The development of roots of accession 9736 is determined by two genes, AlpK1 and AlpK2. The genes have not been not tested for nonidentity. The high tolerance of Faust I shoots are determined by one major tolerance factor and one dominant inhibitor gene, which hampers the manifestation of the dominant tolerance gene. The penetrance of the inhibitor gene may be incomplete. The aluminum sensitivity of roots and 7-day shoots of cv. Faust I is determined by different genetic factors. The response of barley plants to aluminum ions may be determined by small-effect genes.  相似文献   

15.
Exploration of the ability of Coleus blumei to accumulate aluminum   总被引:1,自引:0,他引:1  
In this study, the capacity of an ornamental species (Coleus blumei) to extract and accumulate aluminum was evaluated. The analyzed parameters were amount of soluble aluminum, radical growth, tolerance rate, bioaccumulation factor, and tissues aluminum concentration. The main limiting factor for aluminum accumulation is the availability of the metal. However, Coleus blumei can grow and accumulate up to 1445.7 mg kg(-1) of aluminum dry base. This plant can play an important role in the treatment of polluted water with metals, since it can grow in conditions with a pH of around 4.8. The aluminum tolerance rate showed for this plant ranged between 18.8% and 25%. Therefore, this species behaves as a non-accumulator, even though the bioaccumulation factor was 3098.5 L kg(-1).  相似文献   

16.
低磷和铝毒胁迫条件下菜豆有机酸的分泌与累积   总被引:19,自引:3,他引:16  
沈宏  严小龙 《生态学报》2002,22(3):387-394
以水培方式研究了低磷、铝毒胁迫条件下,不同菜豆基因型根系有机酸的分泌及其在植穆不同部位的累积,结果表明,低磷,铝毒胁迫诱导菜豆有机酸的分泌与累积存在显著的基因差异。低磷、铝毒胁迫诱导菜豆主要分泌柠檬酸、酒石酸和乙酸,其中,50μmol/LAl^3 诱导柠檬酸分泌量最高;低磷(小于20μmol/LH2PO4^-)胁迫诱导柠榨菜酸分泌量显著高于高磷处理,但低磷处理之间差异不明显,铝毒胁迫诱导菜豆有机酸的分泌与累积显著高于低磷胁迫处理,低磷,铝毒胁迫植株不同部位有机酸的含量为叶片大小根系,低磷,铝毒胁迫时,G842菜豆型柠檬酸有机酸分泌总量显著高于273、AFR和ZPV,其干重和磷吸收明明显于大G273,AFR和ZPV,且铝吸收量小于G273,AFR和ZPV,说明,G482菜豆基因型对低磷,铝毒的适应能力强于G273,AFR和ZPV基因型,菜豆有机酸,,尤其柠檬酸的分泌是其适应低磷、铝毒胁迫的重要生理反应。  相似文献   

17.
The study of various factors (soil acidity, the variety of barley plants, and their developmental phases) on the rhizosphere actinomycete complex showed that it is soil acidity that substantially influences the population of rhizosphere actinomycetes. The effect of soil acidity was most likely due to the different tolerance of rhizosphere actinomycetes to high concentrations of the aluminum and hydrogen ions. The developmental phases of barley plants correlated with the population indices of only one genus of actinomycetes, Micromonospora.  相似文献   

18.
MicroRNAs are small 21-nucleotide RNA molecules with regulatory roles in development and in response to stress. Expression of some plant miRNAs has been specifically associated with responses to abiotic stresses caused by cold, light, iron, and copper ions. In acid soils, aluminum solubility increases, thereby causing severe damage to plants. Although physiological aspects of aluminum toxicity in plants have been well characterized, the molecular mediators are not fully elucidated. There have been no reports about miRNA responses to aluminum stress. Modulation of miRNA expression may constitute a key element to explain the mechanisms implicated in aluminum toxicity and tolerance. We examined the expression of at least one miRNA member from each miRNA family in rice roots of Oryza sativa spp indica cv. Embrapa Taim and Oryza sativa spp japonica cv. Nipponbare under high concentrations of aluminum. Forty-six miRNA families were effectively detected by quantitative PCR. Among these, 13 were down-regulated and six were up-regulated in roots of the Nipponbare cultivar after 8 h of aluminum treatment. In roots of the Embrapa Taim cultivar, five miRNAs were down-regulated and three were up-regulated. Analyses of their putative targets suggest that these rice miRNAs are involved in the regulation of various metabolic pathways in response to high concentrations of aluminum.  相似文献   

19.
Somaclonal-variation-induced multiple mutations were observed in a progeny of the S1587 plant, regenerated from type I calli of the aluminum-tolerant inbred maize line Cat-100-6. After five generations of self-pollination, 14 progeny families of the S1587 somaclone were found to show aluminum toxicity symptoms with altered root tip morphology and reduced primary root growth. The most sensitive progeny, S1587-17, was crossed to the Cat-100-6 inbred line. The parental lines and the F1 were tested in nutrient solutions containing an aluminum activity gradient of 0–93 ⋅ 10–6. The heterozygote behaves like the tolerant parent at aluminum activities up to 40 ⋅ 10–6 and showed an intermediate phenotype at higher aluminum concentrations. Histological sections of aluminum-treated roots from tolerant and sensitive plants stained with hematoxylin, an aluminum marker, showed a progressive destruction of the root tip of the aluminum-sensitive genotype over time and indicated that tolerance in Cat-100-6 could be due to an aluminum exclusion mechanism. Segregation analysis of the F2 and backcross to the sensitive parent based on root morphology of plants subjected to an aluminum activity of 30 ⋅ 10–6 showed the typical 3:1 and 1:1 tolerant:sensitive segregation ratios, respectively, indicating that tolerance in the Cat-100-6 inbred maize line is controlled by a single nuclear, semidominant gene, named Alm1. Received: 9 May 1996 / Revision received: 24 February 1997 / Accepted: 8 March 1997  相似文献   

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