植物重金属结合蛋白（肽）

本文综述了植物体中重金属结合蛋白(肽)——类金属硫蛋白(类MT)和植物螯合肽(PC)的诱导产生、物理和生物化学特性及它们的生理功能,并与动物MT作了比较。     

金属结合蛋白(肽)与环境重金属生物修复

重金属污染是全球关注的重要环境问题。针对重金属的生物修复技术 ,因其特有的优势 ,越来越受到重视 ,其中一个重要的研究领域是利用金属离子和金属结合蛋白或结合肽之间存在的强亲和能力特性进行的生物修复研究。就金属结合蛋白 (肽 )的种类、结构特点、以及金属结合的作用机理进行了总结 ,同时综述了展示或表达有不同金属结合蛋白或结合肽的微生物和植物对重金属污染进行生物修复的最新研究进展 ,对基于金属结合蛋白 (肽 )的环境重金属生物修复的进一步研究 (如肽库的构建和筛选 ,金属与蛋白 (肽 )的相互作用 )进行了讨论。     

金属硫蛋白和植物螯合肽在植物重金属耐性中的作用

植物螯合肽和金属硫蛋白广泛存在于植物界中,它们对植物耐重金属特别重要,能够与重金属形成复合物,以缓解重金属对植物的危害。本文就这两种金属螯合蛋白的结构、生物合成和基因调控,以及在植物体内缓解重金属毒害的作用方面作了简要介绍。     

金属结合蛋白基因及其在清除重金属污染中的应用

一些微生物和植物由于对毒性金属具有独特的抗性机制,使得利用它们来清除日益严重的环境污染已发展成为一种十分有效的技术——生物修复。研究表明,不同的金属结合蛋白（如MT 和PC）,在生物忍耐和降解过量重金属毒性机制中起重要作用。愈来愈多的MT 和PC基因被克隆,并已成功地应用于生物遗传转化,这些转基因生物在清除重金属污染方面已显示出潜在的应用价值。 Abstract:Heavy metal pollution has become a global environmental hazard.The use of microorganisms and plants for the decontamination of heavy metals is recognized as a low lost and high efficiency method for cleaning up metal contamination.It shows that various metal-binding proteins such as metallothioneins (MTs) or phytochelatines (PCs) play an important role in defense systems and detoxification to heavy metals in organisms.Many genes of MTs and PCs have been cloned and utilized successfully in genetically modified bacteria and plants for increasing remediation capacity.These transgenic organisms have been displayed a great potential in bioremediation and phytoremediation of heavy metals.     

Cd2+结合肽的筛选及与重金属离子的亲和作用

利用噬菌体随机十二肽库和亲和层析技术对重金属Cd进行亲和筛选,共获得两条Cd结合肽序列。将展示有Cd2 结合肽的噬菌体单克隆扩增物对不同重金属离子(Cd2 、Cr2 、Cu2 、Co2 、Zn2 、Ni2 )螯合的树脂进行亲和测定,结果表明Cu2 、Co2 、Zn2 、Ni2 对结合肽的亲和力高于Cd2 和Cr2 。抑菌解毒试验进一步确认了Cd2 结合肽对大肠杆菌重金属的解毒作用。显微观察可见金属结合肽与金属螯合树脂混合后分散度发生改变。     

家蚕瘫痪肽结合蛋白基因克隆与分析

ENF肽家族具有保守的N末端结构（Glu—Asn—Phe-）。该家族成员肽大多具有重叠功能活性,在鳞翅目昆虫的免疫反应,生长调控和自体调节等方面都发挥着重要的作用。在昆虫的免疫反应中,血细胞尤其是淋巴液的黏附性是针对外来侵入物的免疫应答过程中的重要因素。家蚕瘫痪肽（paralytic peptide）是ENF肽家族的一种,其具有多种的生物学活性,包括致瘫痪性及在家蚕血细胞免疫反应中的促吞噬细胞扩散活性。ENF肽家族的另一成员,粘虫（Pseudaletia separata）的生长阻抑肽（Growth-blocking peptide）,同家蚕瘫痪肽一样能够在粘虫的血细胞免疫反应中起到调节吞噬细胞的功能。目前,关于昆虫细胞免疫应答的终端调控分子机制的研究还比较少,有文献报道粘虫的生长阻抑肽结合蛋白（GBP—BP）能够起到沉默生长阻抑肽活性的功能,从而可能参与调节细胞免疫应答的终端调控。在本研究中,利用荧光差异显示技术（FDD）分析了家蚕感染BmNPV病毒后基因表达差异情况,在血淋巴中获得了一条差异条带G12782＊通过5＇-RACE技术,首次在家蚕中克隆得到了该基因的全长cDNA序列。通过同源性分析得知,该基因所编码的蛋白质与粘虫的生长阻抑肽结合蛋白具有很大的同源性,并被命名为家蚕瘫痪肽结合蛋白（Bmori paralytic peptide binding protein,PP-BP）。通过RT-PCR研究发现,该蛋白基因在血淋巴中大量表达。同时,利用实时荧光定量PCR（Real-time quantitative PCR）技术分析了该基因在正常饲养家蚕与添食BmNPV病毒的家蚕中的表达差异,结果显示该基因在家蚕添食BmNPV病毒后的表达量大大增强,这就暗示该基因可能与BmNPV病毒刺激后所引起的家蚕血液细胞免疫反应相关。利用生物信息学方法对该基因的结构进行了分析,发现该基因具有两个外显子和一个内含子。这个基因已经登入GenBank数据库,收入号为DQ306881。     

微生物展示技术在重金属污染生物修复中的研究进展

自然界对环境金属污染物的迁移和转化具有微秒而复杂的选择控制机理,生物修复技术以其投资少,效率高,可以原位处理低浓度有害污染物的特性而在环境治理中具有极大潜力。考虑传统的生物修复技术常常不能满足重金属治理的要求,基于重金属离子高效结合肽的微生物展示技术,有望在重金属生物修复中发挥重要作用。     

羟喜树碱结合肽的研究

酯化脱水法制备生物素化羟喜树碱,使用Resourse 15反相柱纯化,液质联用分析确证。磺酰罗丹明B染色法鉴定生物素化羟喜树碱的抗癌活性。采用噬菌体展示技术筛选得到14条羟喜树碱结合肽。构建并优化了羟喜树碱结构模型。构建并通过分子动力学优化了羟喜树碱结合肽结构模型。使用分子对接验证并分析了羟喜树碱结合肽与羟喜树碱的结合作用。     

光间受体视黄类物质结合蛋白（IRBP）的研究概况

光间受体视黄类物质结合蛋白 (ＩＲＢＰ)是一种仅在脊椎动物视网膜的光间受体基质 (ＩＰＭ)中发现 ,并由光受体细胞合成并分泌的较大的单亚基糖酯类蛋白 .由于它能够结合各种异构形式和化学形式的视黄类物质和脂酸 ,因而在视循环中作为转移视黄类物质和脂酸的主要运输工具 ,同时也具有保护视黄类物质免于降解和减少视黄类物质潜在的细胞毒性等作用 .除了上述功能外 ,ＩＲＢＰ在调控视黄类物质定位、新陈代谢以及各方面活性等方面也都有不同的特异性功能 ,因而是一种重要的蛋白质成分 .目前对此蛋白质基因结构的研究表明 ,ＩＲＢＰ基因是不包…     

微生物展示技术在重金属污染生物修复中的研究进展

自然界对环境金属污染物的迁移和转化具有微妙而复杂的选择控制机理,生物修复技术以其投资少、效率高、可以原位处理低浓度有害污染物的特性而在环境治理中具有极大潜力。考虑传统的生物修复技术常常不能满足重金属治理的要求,基于重金属离子高效结合肽的微生物展示技术,有望在重金属生物修复中发挥重要作用。     

Ni2+高效结合肽的筛选与作用研究

利用噬菌体随机十二肽库和金属亲和层析对重金属Ni2 进行结合肽筛选。经4轮生物淘洗、噬菌体扩增和DNA测序,获得一组多肽序列。GenBank Blast分析未发现同源序列,Clustal W多重序列比对也未找到Ni2 金属结合肽结合基序,但可能含有多聚组氨酸(His)2-5。噬菌体单克隆金属离子螯合树脂的亲和力测定和反筛、抑菌解毒试验表明:展示有金属结合肽的噬菌体不仅对Ni2 具有高亲和力,而且对其它金属离子也有作用,Cu2 、Ni2 、Co2 、Zn2 等金属离子对金属结合肽的亲和力显著高于Cd2 和Cr2 ,展示金属结合肽的噬菌体对重金属Ni2 具有一定的耐受和解毒作用。显微形态学观察也显示金属结合肽与金属螯合树脂的作用。对于了解重金属与多肽的相互作用机理以及环境重金属修复等均具有重要意义和价值。     

Ribosome display selection of a metal-binding motif from an artificial peptide library

A new ribosome display system was applied for the in vitro selection of a metal-binding motif from an artificial peptide library. The display system consisted of an mRNA-associating protein, a ribosome, and mRNA. The protein part of this display system was designed to provide a random peptide library and to stabilize the ribosome display. The random peptide library was newly designed to isolate stable metal-binding motifs. We employed the system for in vitro selection and found several new proteins and peptides that bind Co(II)-immobilized resin and Co(II)-complex, respectively. This newly developed system can be conveniently applied to the in vitro selection of peptide aptamers.     

Changes in the levels of phytochelatins and related metal-binding peptides in chickpea seedlings exposed to arsenic and different heavy metal ions

Phytochelatin-related peptides were analyzed in chickpea plants exposed to six different heavy-metal ions. Cadmium and arsenic stimulated phytochelatin and homophytochelatin synthesis in roots but other metals did not. These metals, however, caused an overall increase in the precursors, glutathione, homoglutathione and cysteine. These changes may be different biochemical indexes for heavy-metal contamination.     

Molecular mechanisms of heavy metal hyperaccumulation and phytoremediation

A relatively small group of hyperaccumulator plants is capable of sequestering heavy metals in their shoot tissues at high concentrations. In recent years, major scientific progress has been made in understanding the physiological mechanisms of metal uptake and transport in these plants. However, relatively little is known about the molecular bases of hyperaccumulation. In this paper, current progresses on understanding cellular/molecular mechanisms of metal tolerance/hyperaccumulation by plants are reviewed. The major processes involved in hyperaccumulation of trace metals from the soil to the shoots by hyperaccumulators include: (a) bioactivation of metals in the rhizosphere through root–microbe interaction; (b) enhanced uptake by metal transporters in the plasma membranes; (c) detoxification of metals by distributing to the apoplasts like binding to cell walls and chelation of metals in the cytoplasm with various ligands, such as phytochelatins, metallothioneins, metal-binding proteins; (d) sequestration of metals into the vacuole by tonoplast-located transporters. The growing application of molecular-genetic technologies led to the well understanding of mechanisms of heavy metal tolerance/accumulation in plants, and subsequently many transgenic plants with increased resistance and uptake of heavy metals were developed for the purpose of phytoremediation. Once the rate-limiting steps for uptake, translocation, and detoxification of metals in hyperaccumulating plants are identified, more informed construction of transgenic plants would result in improved applicability of the phytoremediation technology.     

Structural analysis of fibroin heavy chain signal peptide of silkworm Bombyx mori

To study the minimal length required for the secretion of recombinant proteins and silkproteins in posterior silk gland,the signal peptide(SP)of the fibroin heavy chain(FibH)of silkwormBombyx mori was systematically shortened from the C-terminal.Its effect on the secretion of protein wasobserved using enhanced green fluorescent protein(EGFP)as a reporter.Secretion of EGFP fusion proteinswas examined under fluorescence microscope.FibH SPs with lengths of 20,18,16 and 12 a.a.can directthe secretion of the reporter,yet those with lengths of 11, 10, 9, 8 and 1 a.a. can not. When the FibH SP wasshortened to 12a.a., the secretion efficiency was decreased slightly and cleavage occurred within EGFP.When 16a.a.of the FibH SP were used,the secretion of fusion protein was normal and the cleavage sitewas between the Gly-Ser linker and Met,the starting amino acid of EGFP. These findings are applicable forthe expression of foreign proteins in silkworm silk gland.The cleavage site of the SP is discussed andcompared with the predictive results of the SignalP 3.0 online prediction program.     

Hyperaccumulators, arbuscular mycorrhizal fungi and stress of heavy metals

Use of plants, with hyperaccumulating ability or in association with soil microbes including the symbiotic fungi, arbuscular mycorrhiza (AM), are among the most common biological methods of treating heavy metals in soil. Both hyperaccumulating plants and AM fungi have some unique abilities, which make them suitable to treat heavy metals. Hyperaccumulator plants have some genes, being expressed at the time of heavy metal pollution, and can accordingly localize high concentration of heavy metals to their tissues, without showing the toxicity symptoms. A key solution to the issue of heavy metal pollution may be the proper integration of hyperaccumulator plants and AM fungi. The interactions between the soil microbes and the host plant can also be important for the treatment of soils polluted with heavy metals.