基于细胞色素c的胞外电子传递过程

电活性微生物具有独特的胞外电子传递功能,在地球化学循环和环境污染修复中起着重要作用。细胞色素c在电活性微生物胞外电子传递过程中扮演了重要角色,不仅参与直接电子传递途径,还参与电子媒介介导的间接电子传递。其电子传递功能不仅对地球环境中铁、锰、碳等元素的循环具有重要作用,还应用于能源生产、废水处理、生物修复等众多领域,具有良好的应用潜力。本文以电活性微生物的2个模式菌属(希瓦氏菌属和地杆菌属)为例,综述了电活性微生物将电子由胞内转移至胞外的方式和途径,详细阐述了细胞色素c在该胞外电子传递过程中的重要作用,总结了细胞色素c介导的胞外电子传递过程所涉及的分析方法,并对微生物胞外电子传递未来的研究方向提出了展望。     

矿物电子能量协同微生物胞外电子传递与生长代谢

微生物的电子传递过程在生命进化和生物地球化学循环中发挥着关键作用。近年来,随着微生物电子传递研究的深入开展,微生物纳米导线、导电生物被膜及种间电子传递等多种新型的微生物胞外电子传递机制不断被发现,微生物电子传递的距离也从纳米级拓展至厘米级。这些微生物的长距离电子传递过程环环相扣、相互协同,从而构成长距离电子传递网络,并在物质循环和能量转化中共同发挥作用。微生物长距离电子传递网络的结构功能及其调控机制已成为多个学科共同关注的焦点。本文以电子传递的距离为主线,对不同尺度的微生物长距离电子传递过程及网络研究的新进展进行综述,包括纳米尺度的电子传递网络（周质空间和外膜表层）、微米至毫米尺度的电子传递网络（纳米导线、细胞间电子和导电生物被膜）、厘米尺度的电子传递网络（电缆细菌）等,并分析了该研究现存的主要问题和下一步的发展方向,以期为进一步推进微生物长距离电子传递网络理论和应用研究提供科学参考。     

微生物胞外呼吸电子传递机制研究进展

胞外呼吸是近年来发现的新型微生物厌氧能量代谢方式,主要包括铁呼吸、腐殖质呼吸与产电呼吸3种形式。微生物胞外呼吸与传统的有氧呼吸、胞内厌氧呼吸存在显著差异。其电子受体多以固态形式存在于胞外;氧化产生的电子必须通过电子传递链从胞内转移到细胞周质和外膜,并通过外膜上的细胞色素c、纳米导线或自身产生的电子穿梭体等方式,最终将电子传递至胞外的末端受体。胞外呼吸的本质问题是微生物与胞外电子受体(铁/锰氧化物、固态电极或腐殖质等)的相互作用,即微生物如何将胞内电子传递至胞外受体。胞外呼吸的研究丰富了人们对微生物呼吸多样性的认识,同时在污染物原位修复及清洁生物能源提取方面具有重要应用前景,是当前研究的热点问题。总结了胞外呼吸类型和胞外呼吸菌的多样性,重点阐述了胞外呼吸的电子传递过程,并提出了其应用前景及今后的研究方向。     

利用高保真酶扩增特性调整基因读码框的方法

在基因工程研究中,经常要涉及到对目的基因读码框进行调整的研究。本文报道了利用高保真DNA聚合酶扩增DNA后产生平末端的特性,及限制性内切酶对一重组的原核表达载体pET28a-HA进行读码框调整的研究,测序结果显示读码框按照预期设计正确调整,表明高保真DNA聚合酶可以用于DNA 3'凹陷端的补平,在DNA 3'凹陷端平滑化时多了一个有效的选择。     

微生物种间直接电子传递机理及应用研究进展

微生物胞内产生的电子转移到其他电子受体而获得能量的过程称为微生物胞外电子传递,其中,另一微生物作为电子受体时发生的电子传递称为微生物种间电子传递。根据微生物种间电子传递机制,可分间接种间电子传递和种间直接电子传递。由于种间直接电子传递不需要其他物质介导,因此较间接种间电子传递效率更高、能量利用更高。本文系统阐述了微生物进行胞外电子传递的机理及应用,重点分析了种间直接电子传递机理,并概述种间直接电子传递应用领域,为寻找更多电连接的微生物群落以及应用微生物提供参考。     

P450酶系中高效电子传递链的构建及应用

细胞色素P450作为单加氧酶的主要成员,能够在多种化合物中引入氧分子,催化包括羟化在内的多种反应。在级联的氧化还原反应中,需特定的电子传递链将氧原子中的电子传递至P450单加氧酶的亚铁红素结构中,并最终催化底物氧化,而电子传递体系的低效性往往成为整个反应的限速步骤。本文在介绍P450单加氧酶电子传递链基本结构的基础上,着重阐述对于细胞色素P450酶系中电子传递链未知或者内源性电子传递效率较低的情况下,利用DNA重组技术构建高效的电子传递链从而提高P450单加氧酶的催化效率相关研究进展,主要从细菌及真核细胞线粒体电子传递链(ClassⅠ)及真核生物细胞色素C还原酶CPR(ClassⅡ),天然融合电子传递链及人工融合蛋白电子传递链的构建及其应用展开。     

微生物种间电子传递的研究进展

种间电子传递可促进微生物发生共代谢,因而在地球生物化学循环和环境污染修复中具有重要意义。根据电子传递方式的不同可将种间电子传递分为直接种间电子传递（direct interspecies electron transfer,DIET）和间接种间电子传递（mediated interspecies electron transfer,MIET）,其中,直接种间电子传递由于易发生、效率高而受到更加广泛的关注。本文总结了近年来关于种间电子传递的研究进展,阐述了种间电子传递的途径,比较了DIET和MIET的优缺点,并对开发更多具有种间电子传递功能的微生物提出了建议,以期加深人们对于种间电子传递的理解,并对未来该领域的研究提供参考。     

光系统I (PSI)的结构与功能研究进展

光系统Ⅰ(PSⅠ)是整合于光合膜上的由多个蛋白亚基组成的色素蛋白复合物,它在光合电子传递链中催化电子从PC经过一系列电子传递体到Fd的传递。近20年特别是近几年来,有关光合作用PSⅠ结构与功能的研究取得了显著的进展,获得了很多具有重要意义的结果。本文综合介绍了近年来在PSⅠ的蛋白亚基组成及其特性、PSⅠ介导的3种电子传递过程、PSⅠ特有的外周捕光色素蛋白复合物系统(LHCⅠ)以及最新的有关PSⅠ 4*!分辨率的三维晶体结构生物学研究的进展情况,并对未来的研究进行了展望。     

由簇毛麦V染色体引起的小麦-簇毛麦染色体代换系、易位系中线粒体蛋白质组的变化(简报)

线粒体是需氧生物中的一种半自主性细胞器.在能量代谢中,它起了一个关键的作用,柠檬酸循环、电子传递和氧化磷酸化过程均在线粒体内完成.线粒体具有高度的生物化学和遗传上的独立性.含有DNA和核糖核蛋白体.负责合成生物体内2%-5%的蛋白质[1].线粒体DNA具有自身复制能力,控制着众多的遗传性状.在植物中广泛存在的细胞质雄性不育则被认为是由线粒体基因组控制的性状[2].     

细胞色素c氧化酶固态薄膜电子传递特性与可擦写纳米存储器

细胞色素c氧化酶的固态薄膜仍具有电子传递活性、其分子内金属活性中心的结构特点及其氧化还原和配位循环变化、光谱特征、物理性控制电子供体或物理性电子供体、开关特性等,使得它适合于分子电子学研究和纳米分子器件的研制,如可擦写纳米存储器.     

5-Deazaflavins: New Very Efficient DNA Photosensitisers,Synthesis of Oligonucleotide Conjugates

Abstract

In order to study electron transfer processes through the DNA double helix, we have synthesised a series of 5-deazaflavin derivatives 1–4 and demonstrated their ability to induce very efficiently 2′-deoxyguanosine and DNA oxidations by electron transfer from guanine. 5-Deazaflavin-oligonucleotide adducts were also synthesised for the study of electron transfers through double or triple helix formed with their complementary sequence.     

Promoted electron transfer of mitoxantrone binding with DNA by cytochrome c

A promoted electron transfer of an antitumor drug, mitoxantrone (MTX), intercalating into DNA duplex was successfully obtained upon addition of cytochromes c (cyt. c) in NaAc-HAc buffer solution (pH 4.5). The experimental results suggested that co-existence of MTX and cyt. c in the DNA helix is an important factor for accelerated electron transfer of MTX, where the promoter, cyt. c, operated smoothly through the DNA bridge. The UV/Vis spectroscopic experiments further confirmed the interaction process. Furthermore, a possible mechanism of such reaction was also discussed in this paper.     

Structure of a photoactive rhodium complex intercalated into DNA

Intercalating complexes of rhodium(III) are strong photo-oxidants that promote DNA strand cleavage or electron transfer through the double helix. The 1.2 A resolution crystal structure of a sequence-specific rhodium intercalator bound to a DNA helix provides a rationale for the sequence specificity of rhodium intercalators. It also explains how intercalation in the center of an oligonucleotide modifies DNA conformation. The rhodium complex intercalates via the major groove where specific contacts are formed with the edges of the bases at the target site. The phi ligand is deeply inserted into the DNA base pair stack. The primary conformational change of the DNA is a doubling of the rise per residue, with no change in sugar pucker from B-form DNA. Based upon the five crystallographically independent views of an intercalated DNA helix observed in this structure, the intercalator may be considered as an additional base pair with specific functional groups positioned in the major groove.     

Interaction between enzyme-generated triplet carbonyls and molecules intercalated into DNA

The phosphorescence from enzyme-generated and -protected triplet acetone is very efficiently quenched by dyes intercalated into DNA. The process is unlikely to be due to energy transfer and is tentatively ascribed to electron transfer occurring within the DNA helix complex with the acting enzyme. This quenching markedly protects DNA from breaks induced by triplet acetone. In the case of some barely emissive enzyme-generated triplet carbonyl species, it is possible to detect a weak emission resulting from the interaction with dye X DNA; this emission may be associated with back electron transfer.     

Use of Oligonucleotide Conjugates in Creating Self-Assembling Supramolecular Systems

Abstract

The chemistry of two types of oligonucleotide conjugates containing novel chromophores are described. One, containing a stilbenedicarboxamide bridge, generates unusually stable hairpin structures that are useful in assessing rates of electron transfer through the π system of a DNA double helix. The other, containing gold nanoparticle conjugates, provides a highly selective system for detecting nucleotide sequences in oligonucleotides.     

Electron injection from the side of an M-DNA duplex

M-DNA is a complex formed between duplex DNA and divalent metal ions (Zn²⁺, Cu²⁺ or Ni²⁺) at pHs above 8. Previous results showed that the fluorescence of an electron donor fluorophore was quenched when an acceptor flourophore was placed in the opposite end of an M-DNA duplex suggesting electron transfer through the duplex and indicating M-DNA may operate as a better conductor than B-DNA. To further investigate the properties of M-DNA, oligodeoxynucleotides were prepared with fluorescein (Fl) as an electron donor placed at different positions along the helix. An internal position of the chromophore was made possible by attaching it to the extra hydroxyl arm in the branched monomer 4′-C-hydroxymethylthymidine. Upon excitation of the donor fluorophore, it was demonstrated that electrons could be injected into the side of an M-DNA helix thereby extending the range of nanoelectronic structures that can be prepared from DNA. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Evidence for structural deformation of the DNA helix by a psoralen diadduct but not by a monoadduct.

We have investigated the structural change in a double-stranded DNA helix caused by covalent addition of a psoralen. A synthetic double-stranded DNA was constructed to contain either a psoralen furan-side monoadduct or an interstrand diadduct at a specific site. When the unmodified and psoralen modified DNAs were examined by electron microscopy in the presence of distamycin, which stiffens the DNA helix, the DNA containing the psoralen interstrand diadduct appeared bent (or kinked), whereas the furan-side monoadducted DNA appeared similar to the unmodified DNA. RecA protein from E. coli has been shown to preferentially bind UV (ultra violet) irradiated DNA presumably due to alterations in the normal DNA helical structure. Using a nitrocellulose filter binding assay, we have found that the psoralen interstrand diadduct enhances the binding of recA protein to the double-stranded DNA, whereas a furan-side monoadduct has little effect. Thus both the recA protein binding and the electron microscopic data suggest that a psoralen diadduct causes deformation of a DNA helix, most likely by kinking the helix, and that a monoadduct has little effect on the DNA helix structure.     

Fluorescent analysis of excess electron transfer through DNA

The DNA base stack provides unique features for the efficient long-range charge transfer. For the purpose of investigating excess electron transfer process through DNA, we developed a new method for fluorescence analysis of excess electron transfer based on reductive cleavage of a disulfide bond and a thiol-specific fluorescent probe. Excess electron transfer was detected by monitoring the fluorescence of emissive pyrene monomer generated by the reaction of pyrene maleimides with the cleaved disulfide bond (thiols). Mechanism of reductive cleavage of disulfides through excess electron transfer and subsequent reaction with the fluorescent probes were discussed. This facile and sensitive detection by fluorescence method can be applied for mechanistic study of excess electron transfer.     

Electrochemistry at DNA-modified surfaces: new probes for charge transport through the double helix

Electrochemistry at DNA-modified surfaces provides an alternative approach to photochemistry or radiation biology for studying charge migration through the double helix. Using short duplexes self-assembled onto gold, electrochemical reduction of redox-active reporter molecules has been observed through DNA films more than 50 A thick, with heterogeneous rate constants as great as approximately 100 s(-1). Though apparently insensitive to base content and sequence, even small distortions in the electronic structure of the pi-stack (caused, for example, by single-base mismatches and other DNA lesions) attenuate the rate of electron transport. Understanding the role of conformational dynamics within the double helix, as well as the cooperative effects of self-assembling individual duplexes into ordered superlattices remain important challenges for theory and experiment.     

Probing DNA charge transport with metallointercalators

A wide range of experiments have emerged recently regarding charge transport through DNA, including spectroscopic studies of rates of DNA-mediated electron transfer and biochemical studies of DNA base oxidation over long distances. These experiments have, in turn, led to new proposals about the way in which charge moves through DNA and have prompted the consideration of physiological roles for DNA electron transfer. Importantly, metallointercalators have been key players in many of these experiments. Metallointercalators provide critical probes to examine the migration of charge through the DNA base stack.