54 resultados para metal tolerance
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日益加剧的重金属污染已经危害到了全球的生态环境以及人类健康。在分子水平上阐明植物中的重金属抗性机制并应用于环境修复和绿色农业是植物科学和环境科学以及农业科学的交叉点和新的生长点。为了了解植物重金属抗性的分子机制,我们的研究主要是从重金属抗性植物材料大蒜(Allium sativumL.)和绊根草(Cynodon dactylon)中分离重金属抗性相关基因,并研究它们在重金属抗性机制中的功能。 在高等植物中有迹象表明,一种富含半胱氨酸的低分子量蛋白.类金属硫蛋白 (Metallothioneins Like,MTs Like)和一类具有Y-(Glu-Cys) n-Gly特殊结构的多肽一植物络合素(Phytochelatins,PCs)在重金属抗性机制中占有重要地位。然而人们对于同一种植物中这两种重金属结合肽作用的相互关系还缺乏了解,同时对于MT Like基因以及PCs合酶基因在同一种植物中的表达模式如金属离子专一性、时空表达特点等,还投有文献报道,因此本文将首先以这两个基因为切入点进行研究。 本研究采用RACE的方法,从大蒜中分离得到了类金属硫蛋白(MT-Like)的cDNA序列(GenBank Accession No.AY050510),PCR和SoutheLrn Blot分析表明,大蒜基因组中不仅存在类金属硫蛋白基因,而且可能以基因家族的形式存在。对获得的MT Like cDNA进行的序列分析及同源性分析表明,大蒜MT Like cDNA含有一个完整的开放阅读框架,编码73个氨基酸,其中12个为半胱氨酸,占氨基酸总数的1 6.4%,并与其他植物如水稻、小麦、紫羊茅草中的类金属硫蛋白基因同源性较高,其中最高达89%。对该基因编码的氨基酸序列和结构分析表明在N-端、c-端结构域中分别含有3个典型的金属硫蛋白的结构模式Cys-Xaa-Cys,属于典型的Type-1类金属硫蛋白。这些Cys-Xaa-Cys特征结构表明大蒜MT Like基因编码的蛋白可以结合二价金属离子。重金属胁迫下大蒜根中MT Like基因在转录水平的表达检测表明,MT Like基因的表达受重金属离子Cu2+、Cd2+的诱导,暗示MT Like基因在大蒜对重金属的抗性中有重要作用。此外,用能谱电镜技术研究大蒜中重金属的积累与分布,以及用组织原位杂交技术分析MT Like基因的表达定位与重金属的积累、转运的关系已在进行之中。 植物络合素也是富含巯基的多肽化合物,在重金属抗性中起重要作用。由植物络合素结构中存在的Y一酰胺键或β-Ala可知PCs不是基因表达的直接产物,而是以GSH为前体的酶促反应产物。目前已知y一谷氨酰半胱氨酸二肽转肽酶(简称为PCs合酶,phytochelatin synthase,PCS)是PCs合成途径的关键酶,编码这一关键酶的基因目前已在小麦、拟南芥菜和裂殖酵母中克隆。由于这一基因在不同物种中的保守性较低,其克隆较困难。本研究通过设计植物络合素台酶基因简并引物,从大蒜中扩增得到了345bp的cDNA序列。序列分析和推测的氨基酸序列同源性比较表明,此序列的翻译产物与已知的植物络合素合酶同源性最高,此cDNA序列应为大蒜植物络合素合酶基因的部分cDNA序列(GenBank Accession No.AF384110)。目前大蒜植物络台素合酶基因的全长序列的扩增,以及这两种与重金属抗性有关的基因(MT Like,PCS)的表达模式仍在研究中。 本文还尝试了利用酵母重金属敏感突变株M379/8功能互补的方法从重金属抗性植物绊根革中分离新的重金属抗性相关基因。构建了用于转化的酵母质粒表达文库,探索了酵母转化体系建立的条件。曾尝试多种转化方法,并对其中的条件进行了优化改进。下一步的工作将集中在合适的酵母突变体的筛选或穿梭表达载体的选择标记基因替换上
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本研究利用酵母功能互补方法和RACE的方法从具有较强抗逆能力的绊根草中克隆了9个与重金属抗性相关的克隆,并对部分基因的表达调控及功能进行了初步研究。同时还利用细胞工程技术筛选到了具有较强的耐受火箭推进齐-偏二甲肼(UDMH)的芦苇的变异株系,为以后用人工湿地系统处理受偏二甲肼污染的废水奠定了基础。 本研究通过酵母功能互补法克隆到了五个基因,分别为CdSRP、CdTETH、 CdASP、CdMT2和CdTER1。CdSRP可能是一种衰老相关基因;CdTETH编码的产物可能是组成TRAPP复合体的一个亚基;CdASP是一个功能未知的基因;CdMT2是一个编码Type Ⅱ型金属硫蛋白基因;CdTER1可能是编码一个TERl-like家族蛋白成员的基因。用这五个基因分别转化因Acr基因缺失而对As敏感的酵母菌株FD236-6A,所获得的转化子对As的抗性均有提高,其中以CdMT2、CdTER1和CdASP的作用最为明显。这些基因的表达调控方式以及与其它重金属抗性的关系正在研究中。 本研究还利用RACE的方法克隆了一个谷胱甘肽S-转移酶基因,CdGSTFl;两个植物络合素合酶基因,CdPCSI和CdPCSⅡ,和一个TypeⅠ型金属硫蛋白基因CdMT1。CdGSTF1属于phi类GST基因,Northern-blotting分析表明,CdGSTF1在绊根草根部的表达受Cd2+的诱导,暗示其可能具有解除氧自由基或氢过氧化物的毒性的作用。CdPCSI和CdPCSⅡ的同源性较高,表明绊根草含有两个以上的PCs合酶的基因。参照前人的方法对CdPCSI和CdPCSII的氨基酸序列进行分析,发现它们含有六个非常相近的Cd2+结合位点,这两个基因的功能及其调控方式有何差异尚需进一步的研究。cdMT1与用酵母功能互补法克隆到的CdMT2属于不同类型的MT基因,对它们之间很可能存在的功能、组织特异性等方面的差异性进行了讨论。 四氧化二氮/偏二甲肼是常用的航天器双组元液体推进剂。偏二甲肼易挥发,有致癌、致畸、致突变的毒性。在推进剂贮存、运输、转注、火箭发动机试车、火箭发射、管道及设备冲洗中产生的含有偏二甲肼的废水能够对卫星发射基地的地下水源和空气造成污染。因此迫切需要培育能够净化偏二甲肼污水的植物。 本研究利用生长在卫星发射基地的野生芦苇的种子诱导愈伤组织,进而通过逐步提高偏二甲肼筛选压力的方式从中筛选出具有较强抗性的愈伤组织,然后诱导其分化。目前已经得到能够在含有1.63 mmol/L和3.26 mmol/L偏二甲肼的分化培养基中生长良好的芦苇再生苗,并已成功转移至温室中。抗性分化苗对污水的处理效果和耐受偏二甲肼的机理正在研究中。
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植物耐受和积累重金属的细胞学基础是植物细胞内存在一些能够络合和区隔化金属离子的机制。细胞中络合重金属离子最重要的小肽分子是谷胱甘肽(GSH)和植物络合素(PCs),而YCFⅠ基因编码的ABC-type 液泡膜转运蛋白负责将重金属离子及其与上述小肽形成的复合物转运进入细胞液泡中,即将重金属离子区隔化。植物细胞中合成GSH 和PCs 的关键酶分别是γ-谷氨酰氨半胱氨酸合成酶(GSHⅠ)和植物络合素合酶(PCS),他们的编码基因分别为GSHⅠ 和PCS 。此外定位于细胞质中的小囊泡上且对二价阳离子的吸收和转运有重要作用的SMF2 蛋白可能也参与重金属离子的区隔化过程。 为了改良植物使之能够应用于清除土壤中的重金属污染,本研究基于植物耐受和积累重金属的细胞学机制,分别将酿酒酵母来源的GSHⅠ、YCFⅠ和SMF2 基因,以及GSHⅠ、YCFⅠ基因分别与镉抗性植物大蒜来源的AsPCSⅠ 基因构建为不同的基因组合表达载体,转化模式植物拟南芥。对不同组合转基因拟南芥的功能分析表明: 1、酵母来源的基因GHSⅠ、YCFⅠ分别在拟南芥中异源超表达可以在一定程度上提高转基因拟南芥耐受、积累重金属的能力;其中GSHⅠ基因在拟南芥超表达可以提高转基因拟南芥合成GSH 的能力,转基因拟南芥细胞中GSH 浓度比野生型增加。 2、将GSHⅠ基因和来自大蒜的AsPCSⅠ基因同时在拟南芥中超表达能够显著提高转基因拟南芥耐受和积累重金属的能力,且积累和耐受能力显著高于分别转GSHⅠ或AsPCSⅠ的单价转基因株系;将YCFⅠ基因和AsPCSⅠ基因同时在拟南芥中超表达也能够显著提高转基因拟南芥耐受和积累重金属的能力,且积累和耐受能力显著高于分别转YCFⅠ或AsPCSⅠ的单价转基因株系。两种双价转基因株系GSHⅠ+AsPCSⅠ和YCFⅠ+AsPCSⅠ在积累和耐受不同重金属胁迫方面没有明显差别。 3、将SMF2 基因在拟南芥中异源表达,研究了植物中囊泡转运是否参与了重金属离子的吸收和区隔化过程。研究结果表明:超表达SMF2 基因的拟南芥尽管耐受重金属胁迫的能力与野生型没有明显差异,但其积累重金属的能力显著提高。这为证明植物中小囊泡转运参与重金属转运提供了间接证据。 综上所述,同时将多个参与植物对重金属络合、转运和区隔化作用的关键基因在转基因植物中表达可以提高植物耐受和积累重金属的能力,是培育可用于植物修复的新型工程植物的值得探索的途径。本论文所设计和构建的双价基因组合及其对目标植物的转化,在环境重金属污染的清除中有潜在的应用价值。
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Monotopic membrane proteins are membrane proteins that interact with only one leaflet of the lipid bilayer and do not possess transmembrane spanning segments. They are endowed with important physiological functions but until now only few of them have been studied. Here we present a detailed biochemical, enzymatic and crystallographic characterization of the monotopic membrane protein sulfide:quinone oxidoreductase. Sulfide:quinone oxidoreductase is a ubiquitous enzyme involved in sulfide detoxification, in sulfide-dependent respiration and photosynthesis, and in heavy metal tolerance. It may also play a crucial role in mammals, including humans, because sulfide acts as a neurotransmitter in these organisms. We isolated and purified sulfide:quinone oxidoreductase from the native membranes of the hyperthermophilic bacterium Aquifex aeolicus. We studied the pure and solubilized enzyme by denaturing and non-denaturing polyacrylamide electrophoresis, size-exclusion chromatography, cross-linking, analytical ultracentrifugation, visible and ultraviolet spectroscopy, mass spectrometry and electron microscopy. Additionally, we report the characterization of its enzymatic activity before and after crystallization. Finally, we discuss the crystallization of sulfide:quinone oxidoreductase in respect to its membrane topology and we propose a classification of monotopic membrane protein crystal lattices. Our data support and complement an earlier description of the three-dimensional structure of A. aeolicus sulfide:quinone oxidoreductase (M. Marcia, U. Ermler, G. Peng, H. Michel, Proc Natl Acad Sci USA, 106 (2009) 9625-9630) and may serve as a reference for further studies on monotopic membrane proteins. (C) 2010 Elsevier B.V. All rights reserved.
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For metal-matrix composites (MMCs), interfacial debonding between the ductile matrix and the reinforcing hard inclusions is an important failure mode. A fundamental approach to improving the properties of MMCs is to optimize their microstructure to achieve maximum strength and toughness. Here, we investigate the flow stress of a MMC with a nanoscale microstructure similar to that of bone. Such a 'biomorphous' MMC would be made of staggered hard and slender nanoparticles embedded in a ductile matrix. We show that the large aspect ratio and the nanometer size of inclusions in the biomorphous MMC lead to significantly improved properties with increased tolerance of interfacial damage. In this case, the partially debonded inclusions continue to carry mechanical load transferred via longitudinal shearing of the matrix material between neighboring inclusions. The larger the inclusion aspect ratio, the larger is the flow stress and work hardening rate for the composite. Increasing the volume concentration of inclusion also makes the biomorphous MMC more tolerant of interfacial damage.
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A novel method was developed to prepare the highly active Pt-Ru-P/C catalyst. The deposition of phosphorus significantly increased electrochemical active surface (EAS) area of catalyst by reduces Pt-Ru particle size. TEM images show that Pt-Ru-P nanoparticles have an uniform size distribution with an average diameter of 2 nm. Cyclic voltammetry (CV), Chronoamperometry (CA), and CO stripping indicate that the presence of non-metal phosphorus as an interstitial species Pt-Ru-P/C catalyst shows high activity for the electro-oxidation of methanol, and exhibit enhanced performance in the oxidation of carbon monoxide compared with Pt-Ru/C catalyst. At 30 degrees C and pure oxygen was fed to the cathode, the maximum power density of direct methanol fuel cell (DMFC) with Pt-Ru-P/C and Pt-Ru/C catalysts as anode catalysts was 61.5 mW cm(-2) and 36.6 mW cm(-2), respectively. All experimental results indicate that Pt-Ru-P/C catalyst was the optimum anode catalyst for direct methanol fuel cell.
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The strengthening behavior of particle-reinforced metal-matrix composites (MMCp) is primarily attributed to the dislocation strengthening effect and the load-transfer effect. To account for these two effects in a unified way, a new hybrid approach is developed in this paper by incorporating the geometrically necessary dislocation strengthening effect into the incremental micromechanical scheme. By making use of this hybrid approach, the particle-size-dependent inelastic deformation behavior of MMCp is given. Some comparisons with the available experimental results demonstrate that the present approach is satisfactory.
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The material response and failure mechanism of unidirectional metal matrix composite under impulsive shear loading are investigated in this paper. Both experimental and analytical studies were performed. The shear strength of unidirectional C-f/A356.0 composite and A356.0 aluminum alloy at high strain rate were measured with a modified split Hopkinson torsional bar technique. The results indicated that the carbon fibers did not improve the shear strength of aluminum matrix if the fiber orientation aligned with the shear loading axis. The microscopic inspection of the fractured surface showed a multi-scale zigzag feature which implied a complicated shear failure mechanism in the composite. In addition to testing, the micromechanical stress field in the composite was analyzed by the generalized Eshelby equivalent method (GEEM). The influence of cracking in matrix on the micromechanical stress field was investigated as well. The results showed that the stress distribution in the composite is quite nonhomogeneous and very high shear stress concentrations are found in some regions in the matrix. The high shear stress concentration in the matrix induces tensile cracking at 45 degrees to the shear direction. This in turn aggravates the stress concentration at the fiber/matrix interface and finally leads to a catastrophic failure in the composite. From the correlation between the analysis and experimental results, the shear failure mechanism of unidirectional C-f/A356.0 composite can be elucidated qualitatively.
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A systematic approach is proposed to obtain the interfacial interatomic potentials. By inverting ab initio adhesive energy curves for the metal-MgO ceramic interfaces, We derive interfacial potentials between Ag and O2-, Ag and Mg2+, Al and O2-, Al and Mg2+. The interfacial potentials, obtained from this method, demonstrate general features of bondings between metal atoms and ceramic ions.
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The effect of thermally activated energy on the dislocation emission from a crack tip in BCC metal Mo is simulated in this paper. Based on the correlative reference model on which the flexible displacement boundary scheme is introduced naturally, the simulation shows that as temperature increases the critical stress intensity factor for the first dislocation emission will decrease and the total number of emitted dislocations increase for the same external load. The dislocation velocity and extensive distance among partial dislocations are not sensitive to temperature. After a dislocation emission, two different deformation slates are observed, the stable and unstable deformation states. In the stable deformation slate, the nucleated dislocation will emit from the crack tip and piles up at a distance far away from the crack tip, after that the new dislocation can not be nucleated unless the external loading increases. In the unstable deformation state, a number of dislocations can be emitted from the crack lip continuously under the same external load.
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The mechanical behaviors of 2124, Al-5Cu, Al-Li and 6061 alloys reinforced by silicon carbide particulates, together with 15%SiCw/6061 alloy, were studied under the quasi-static and impact loading conditions, using the split Hopkinson tension/compression bars and Instron universal testing machine. The effect of strain rate on the ultra tensile strength (UTS), the hardening modulus and the failure strain was investigated. At the same time, the SEM observations of dynamic fracture surfaces of various MMC materials showed some distinguished microstructures and patterns. Some new characteristics of asymmetry of mechanical behaviors of MMCs under tension and compression loading were also presented and explained in details, and they could be considered as marks to indicate, to some degree, the mechanism of controlling damage and failure of MMCs under impact loading. The development of new constitutive laws about MMCs under impact loading should benefit from these experimental results and theoretical analysis.
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In this paper, the effect of particle size on the formation of adiabatic shear band in 2024 All matrix composites reinforced with 15% volume fraction of 3.5, 10 and 20 mum SiC particles was investigated by making use of split Hopkinson pressure bar (SHPB). The results have demonstrated that the onset of adiabatic shear banding in the composites strongly depends on the particle size and adiabatic shear banding is more readily observed in the composite reinforced with small particles than that in the composite with large particles. This size dependency phenomenon can be characterized by the strain gradient effect. Instability analysis reveals that high strain gradient is a strong driving force for the formation of adiabatic shear banding in particle reinforced metal matrix composites (MMCp).
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Dislocation models with considering the mismatch of elastic modulus between matrix and reinforcing particles are used to determine the effective strain gradient \ita for particle reinforced metal matrix composites (MMCp) in the present research. Based on Taylor relation and the kinetics of dislocation multiplication, glide and annihilation, a strain gradient dependent constitutive equation is developed. By using this strain gradient-dependent constitutive equation, size-dependent deformation strengthening behavior is characterized. The results demonstrate that the smaller the particle size, the more excellent in the reinforcing effect. Some comparisons with the available experimental results demonstrate that the present approach is satisfactory.