植物线粒体DNA质粒研究进展

本文列出了已发现的高等植物中的线粒体DNA质粒,按分子形状分为线粒体环状DNA质粒和线粒体线状DNA质粒,环状线粒体DNA质粒的特征是分子较小, 序列中有正向/反向重复序列,ORF一般较小。线状线粒体DNA质粒的特征是分子较大,末端有重复序列,5'端与蛋白质共价结合,有较长的ORF。还分别介绍了它们的复制机制、转录和起源。质粒间及质粒与核基因组、线粒体基因组、叶绿体基因组的同源性也作了介绍。最后,综述了植物线粒体DNA质粒与植物的细胞质雄性不育（CMS）之间的关系。     

黄瓜线粒体DNA类质粒pC1的性质和核酸序列研究

津研四号黄瓜线粒体中除主环ＤＮＡ外,还有４种ＤＮＡ类质粒：ｐＣ１、ｐＣ２、ｐＣ３、ｐＣ４。将环形类质粒ｐＣ１ｌｐｋ ｇｃ ｐＵＣ１９的ＥｃｏＲⅠ位点上,克隆至Ｅ．ｃｏｌｉ ＪＭ１０９中。以克隆的ｐＣ１为探针,进行同源性检测,ｐＣ１与津研四号黄瓜的核基因组、叶绿体基因组、线粒体基因组和线粒体中其他类质粒不同源。对ｐＣ１进行序列测定和分析,ｐＣ１长度２ ８８９ｂｐ,含有多个正向和反向重复序列,有３个８     

E和St基因组特异RAPD片段在部分小麦族植物中的分布

两个Ｅ基因组（包括Ｅｅ和Ｅｂ）特异ＲＡＰＤ片段和两个Ｓｔ基因组特异ＲＡＰＤ片段的序列分析表明,４个片段均为新的ＤＮＡ克隆片段。染色体原位杂交显示ＯＰＤ１２４４４为区域化连续高度重复序列,而ＯＰＦ０３１２９６（Ｅｂ特异）、ＯＰＢ０８５２５（Ｓｔ特异）、ＯＰＮ０１８１７（Ｓｔ特异）为弥散性高度重复序列。研究还显示：大部分ＤＮＡ高度重复序列在亲缘关系较近的小麦族植物基因组间是共享的,差异可能主要是在重复次数及片段长度上,而能否用ＲＡＰＤ技术扩增主要决定于某一基因组的这些重复序列中有无与特定引物相匹配的区域。文中就这些重复序列在小麦远缘杂交后代外源遗传物质检测、多倍体物种染色体组组成研究中的潜在价值进行了讨论。     

原子力显微镜研究不同温度下质粒DNA结构变化

采用原子力显微镜（ＡＦＭ）在无水乙醇中成象了ｐＢＲ３２２质粒ＤＮＡ。在不同温度范围加热云母表面的ＤＮＡ溶液,并在相应温度下干燥使ＤＮＡ充分展开地固定在云母基底上。ＡＦＭ观察结果表明：在３０～４０℃,质粒ＤＮＡ主要是超螺旋和环状分子;在４０～５０℃,环状分子开环形成线形分子;　在７０～８０℃,这些线形分子全部变性,解链形成无规线团。我们通过测定ｐＢＲ３２２质粒ＤＮＡ的熔融曲线,发现了两个突变点,对应于ＡＦＭ所观察到的质粒ＤＮＡ在加热过程中由环状变成线形、双螺旋解开成单链的两个结构变化过程。这是首次通过ＡＦＭ直接观察到质粒ＤＮＡ在不同温度下的结构变化。     

一种从鱼类卵巢制备地高辛标记mtDNA探针的简易方法

一种从鱼类卵巢制备地高辛标记ｍｔＤＮＡ探针的简易方法＊ＡＳＩＭＰＬＥＭＥＴＨＯＤＦＯＲＧＥＴＴＩＮＧＤＩＧＯＸＩＧＥＮＩＮＬＡＢＥＬＩＮＧＰＲＯＢＬＥＯＦｍｔＤＮＡＦＲＯＭＯＶＡＲＹＯＦＦＩＳＨ关键词鱼类,线粒体ＤＮＡ,地高辛标记ＫｅｙｗｏｒｄｓＦｉ...     

杂交水稻及其“三系”线粒体DNA的AP—PCR指纹图谱

为了研究水稻（Ｏｒｙｚａ ｓａｔｉｖａ Ｌ．）细胞质雄性不育（ＣＭＳ）与线粒体基因组的关系,应用ＡＰ－ＰＣＲ 分析,用７ 个任意单引物对６ 种水稻品系线粒体ＤＮＡ 进行了扩增。水稻线粒体ＤＮＡ 的ＡＰ－ＰＣＲ 产物可分为三种类型：（１）所有供试品系均能扩增的片段,它们代表了线粒体ＤＮＡ 在进化上的保守性序列。有４ 个引物检测到这类片段。（２）２ 个以上水稻品系共同出现而在全部供试材料间存在差异的扩增片段,这类片段是检测水稻线粒体ＤＮＡ多态性的主要来源。（３）一种细胞质类型所特有的扩增片段,从引物Ｒ２ 和Ｖ５ 的扩增产物中发现了这类片段,它们可能与ＣＭＳ有关联。另外,ＷＡ型不育系珍汕９７Ａ 与其杂种之间在６ 个引物的扩增图谱上均存在不同程度的差异,说明两者的线粒体ＤＮＡ序列结构可能存在某种差别     

线性质粒

在染色体外DNA分子的研究领域中,一支异军正在悄悄突起,这就是线性质粒的研究。 迄今报导的多数质粒都是环状的DNA分子。近年来,人们相继在真核生物中发现了一些线状质粒。例如,玉米线粒体中的SⅠ和SⅡ质粒(1,2)、Sarghum线粒体中质粒(8)、真菌Ascobolus immersus中的质粒。     

高等植物DNA重复序列的主要类型和特点

高等植物核基因组的一个显著特征是其内含有大量的ＤＮＡ重复序列,因此它们在核基因组结构和功能研究中居于举足轻重的地位。一些ＤＮＡ重复序列已日趋广泛地作为分子民用于构建遗传图谱、鉴别品种、研究进化和分离目标基因等。主要介绍高等植物几类重要ＤＮＡ重复序列,如卫星ＤＮＡ、微卫星ＤＮＡ、核糖体ＲＮＡ基因、端粒重复序列和转座子等的若干特点和用途。     

中华卵索线虫线粒体基因组多态性分析

为完善昆虫病原索科线虫线粒体基因组全序列数据库, 更系统地研究其基因组特征和系统演化规律, 进而为发挥该线虫生防潜力打下基础, 我们开展了中华卵索线虫Ovomermis sinensis线粒体全基因组的研究。该研究通过线粒体基因组滚环复制及酶切图谱, 揭示了中华卵索线虫线粒体基因组具有种内遗传多态性, 即群体中单体线虫具有独特的酶切条带, 且条带累加之和变化范围较大, 为16.5～24.5 kb。为进一步了解线粒体基因组多态性特征及产生的分子机制, 采用两步长PCR方法对2条代表性成虫线粒体基因组进行了测序及拼接, 得其全长分别为18 864和16 777 bp。对这2条序列的比对表明, 线粒体基因组中位于ND2和ND4之间的可变区域, 不仅基因排列顺序不同, 且存在ND3基因重复现象, 这是导致中华卵索线虫线粒体基因组呈现多态性的主要原因。通过对以上研究结果的分析及与GenBank中已有的6种索科线虫线粒体基因组序列进行比对, 概括出其线粒体基因组基本特点: ①线粒体基因排列顺序各不相同;②部分线虫线粒体基因存在重复现象, 且重复次数不同;③线粒体基因组大小存在很大差异。     

动物线粒体基因组变异研究进展

动物mtDNA大多是共价闭合的环状双链分子,一般由2个非编码区和37个编码基因组成,不同动物线粒体基因组大小变异明显.孑遗疟虫(Plasmodium reichenowi)的线粒体基因组最小,仅为5966bp;领鞭毛虫(Monosiga brevicollis)的最大,达76568bp.动物线粒体基因组大小变异的原因主要有:控制区串联重复元件的变异;基因重复;基因重叠与基因间隔区大小的差异;基因缺失和增加.     

Linear plasmids in plant mitochondria: Peaceful coexistences or malicious invasions?

Plant mitochondria contain small extrachromosomal DNAs in addition to a large and complex main mitochondrial genome. These molecules can be regarded as extrachromosomal replicons or plasmids, of which there are two forms, circular and linear. Linear mitochondrial plasmids are present in many fungi and in some plants, but they seem to be absent from most animal cells. They usually have a common structural feature, called an invertron, that is characterized by the presence of terminal inverted repeats and proteins covalently attached to their 5 termini. Linear mitochondrial plasmids possess one to six ORFs that can encode unknown proteins but often code for the DNA and RNA polymerases. Although the functions of most linear plasmids in plant mitochondria are unknown, some plasmids may be associated with mitochondrial genome rearrangements and may have phenotypic effects due to their integration into mitochondrial genome. The Brassica 11.6-kb plasmid, one of the linear mitochondrial plasmids in plants, shows a non-maternal inheritance, in contrast to mitochondrial genomes. The origin of these plasmids is still a mystery, but indirect evidence indicates the possibility of horizontal transfer from fungal mitochondria. In this review, the main features of these unique DNAs present in plant mitochondria are described.     

Cloning and characterization of a linear 2.3 kb mitochondrial plasmid of maize

Summary A linear 2.3 kb DNA molecule found in maize mitochondria was cloned into pUC8. A natural deletion of this plasmid, found in cmsT and some N (fertile) types of maize plants, was mapped to one end of the plasmid. A minor sequence homology to S-2, another linear mitochondrial plasmid, was detected, as well as more significant sequence homology with chloroplast and maize nuclear DNA. Hybridization to teosinte mitochondrial DNA (mtDNA) revealed the presence of part of the maize plasmid in the high molecular weight mtDNA of the maize relatives. RNA dot hybridization indicates that the plasmid is transcribed in mitochondria. The termini of the 2.3 kb linear plasmid contain inverted repeated sequences; of the first 17 nucleotides of the termini, 16 are identical to the terminal inverted repeats of the linear S plasmids found in the mitochondria of cmsS maize plants.     

Characterization of two new plasmid DNAs found in mitochondria of wild-type Neurospora intermedia strains

Mitochondria from two Neurospora intermedia strains (P4O5-Labelle and Fiji N6-6) were found to contain plasmid DNAs in addition to the standard mitochondrial DNA species. The plasmid DNAs consist of monomeric circles (4.1-4.3 kbp and 5.2-5.3 kbp for Labelle and Fiji, respectively) and oligomers in which monomers are organized as head-to-tail repeats. DNA-DNA hybridization experiments showed that the plasmids have no substantial sequence homology to mtDNA, to each other, or to a previously characterized mitochondrial plasmid from N. crassa strain Mauriceville-lc (Collins et al. Cell 24, 443-452, 1981). The intramitochondrial location of the plasmids was established by cell fractionation and nuclease protection experiments. In sexual crosses, the plasmids showed strict maternal inheritance, the same as Neurospora mitochondrial DNA. The plasmids may represent a novel class of mitochondrial genetic elements.     

Circular and linear plasmids of Lyme disease spirochetes have extensive homology: characterization of a repeated DNA element.

We have cloned three copies of a repeated DNA segment from Borrelia burgdorferi sensu stricto strain B31, present on both circular and linear plasmids of this and other B. burgdorferi sensu lato strains. The DNA sequences are characterized by a highly homologous segment containing two open reading frames (ORFs), ORF-A and ORF-B. Five additional ORFs can be found on the slightly less homologous flanking sequences: ORF-G on the opposite strand upstream of ORF-A, and ORF-C, ORF-D, ORF-E, and ORF-F downstream of ORF-B. The 4.6-kb-long element containing ORF-A through ORF-E is flanked by approximately 180-bp-long imperfect inverted repeats (IRs). The putative gene product of ORF-C displays homology to proteins involved in plasmid maintenance in a number of gram-positive and gram-negative bacteria. ORF-E features several short, highly homologous direct repeats. ORF-A, ORF-B, and ORF-D are homologous to three ORFs on a recently described 8.3-kb circular plasmid of Borrelia afzelii Ip21 that are flanked by similar IRs (J. J. Dunn, S. R. Buchstein, L.-L. Butler, S. Fisenne, D. S. Polin, B. N. Lade, and B. J. Luft, J. Bacteriol. 176:2706-2717,1994). ORF-C and ORF-E, however, are missing from this region on the Ip21 plasmid. Furthermore, the repeated DNA element as defined by the IRs is present in opposite orientations relative to the flanking sequences on the B31 and Ip21 plasmids.     

Structural features and expression analysis of a linear mitochondrial plasmid in rapeseed (Brassica napus L.)

A linear plasmid molecule about 11 kb in length is present in the mitochondria of some varieties of rapeseed (Brassica napus L.). This plasmid can be inherited from the male parent, through the pollen, as well as by the usual maternal route, although the main mitochondrial genome is maternally inherited in rapeseed. We determined the complete nucleotide sequence of this plasmid DNA and clarified its genetic organization. The length of the linear plasmid is 11,640 bp. At the termini of the plasmid molecule are inverted repeats of 327 bp. The GC content of the plasmid DNA is 30.9%; thus, the plasmid is quite AT-rich compared to the main mitochondrial genome in higher plants. The plasmid has six ORFs, two of which encode a phage-type DNA polymerase and a phage-type RNA polymerase, respectively. RT-PCR analyses revealed that all six ORFs are transcribed, and all four ORFs on the minus strand are probably cotranscribed from a single promoter located in the terminal inverted repeat. We also show here that at least three of the six ORFs are translated into proteins in rapeseed mitochondria, and expressed at relatively high levels in flowers, as shown by Western analysis. These results suggest that this linear DNA molecule is able to replicate as an autonomous replicon and to express the genes it carries in rapeseed mitochondria.     

Identification of the Mitochondrial Genome in the Chrysophyte Alga Ochromonas danica

ABSTRACT. Analysis of total DNA isolated from the Chrysophyte alga Ochromonas danica revealed, in addition to nuclear DNA, two genomes present as numerous copies per cell. The larger genome (?120 kilobase pairs or kbp) is the plastid DNA, which is identified by its hybridization to plasmids containing sequences for the photosynthesis genes rbcL, psbA, and psbC. The smaller genome (40 kbp) is the mitochondrial genome as identified by its hybridization with plasmids containing gene sequences of plant cytochrome oxidase subunits I and II. Both the 120- and 40-kbp genomes contain genes for the small and large subunits of rDNA. The mitochondrial genome is linear with terminal inverted repeats of about 1.6 kbp. Two other morphologically similar species were examined, Ochromonas minuta and Poteriochromonas malhamensis. All three species have linear mitochondrial DNA of 40 kbp. Comparisons of endonuclease restriction-fragment patterns of the mitochondrial and chloroplast DNAs as well as those of their nuclear rDNA repeats failed to reveal any fragment shared by any two of the species. Likewise, no common fragment size was detected by hybridization with plasmids containing heterologous DNA or with total mitochondrial DNA of O. danica; these observations support the taxonomic assignment of these three organisms to different species. The Ochromonas mitochondrial genomes are the first identified in the chlorophyll a/c group of algae. Combining these results with electron microscopic observations of putative mitochondrial genomes reported for other chromophytes and published molecular studies of other algal groups suggests that all classes of eukaryote algae may have mitochondrial genomes < 100 kbp in size, more like other protistans than land plants.     

Sequence organization of the circular plasmid pKD1 from the yeast Kluyveromyces drosophilarum.

pKD1 is the only circular plasmid known in the genus Kluyveromyces. Nucleotide sequence analysis has revealed that this 4757 base-pairs long plasmid contained three major open reading frames, A, B, and C, and a pair of inverted repeats of 346 base-pairs. The molecule exists in two isomeric forms generated by internal recombination at these repeats. The functional organization of pKD1 genome appears to be quite analogous to that of the 2u plasmid of Saccharomyces cerevisiae. There is however little homology of sequences between these plasmids, except that the gene A has a dispersed but significant homology with the FLP recombinase gene of the 2u plasmid. S.cerevisiae cells can be transformed by derivatives of pKD1 carrying URA3 gene as a selection marker.     

The Agrocybe aegerita mitochondrial genome contains two inverted repeats of the nad4 gene arisen by duplication on both sides of a linear plasmid integration site.

The Agrocybe aegerita mitochondrial genome possesses two polB genes with linear plasmid origin. The cloning and sequencing of the regions flanking Aa-polB P1 revealed two large inverted repeats (higher than 2421 nt) separated by a single copy region of 5834 nt. Both repeats contain identical copies of the nad4 gene. The single copy region contains two disrupted genes with plasmid origin Aa-polB P1 and a small ORF homologous to a small gene described in two basidiomycete linear plasmids. The phylogenetic analyses argue in favor of a same plasmid origin for both genes but, surprisingly, these genes were separated by a mitochondrial tRNA-Met. Both strands of the complete region containing the two nad4 inverted copies and the tRNA-Met appear to be transcribed on large polycistronic mRNAs. A model summarizing the events that would have occurred is proposed: (1) capture of the tRNA by the plasmid before its integration in the mtDNA or acquisition of the tRNA gene by recombination after the plasmid integration, (2) integration of the plasmid in the mtDNA, accompanied by a large duplication containing the nad4 gene and (3) erosion of the plasmid sequences by large deletions and mutations.     

The Agrocybe aegerita mitochondrial genome contains two inverted repeats of the nad4 gene arisen by duplication on both sides of a linear plasmid integration site

The Agrocybe aegerita mitochondrial genome possesses two polB genes with linear plasmid origin. The cloning and sequencing of the regions flanking Aa-polB P1 revealed two large inverted repeats (higher than 2421 nt) separated by a single copy region of 5834 nt. Both repeats contain identical copies of the nad4 gene. The single copy region contains two disrupted genes with plasmid origin Aa-polB P1 and a small ORF homologous to a small gene described in two basidiomycete linear plasmids. The phylogenetic analyses argue in favor of a same plasmid origin for both genes but, surprisingly, these genes were separated by a mitochondrial tRNA-Met. Both strands of the complete region containing the two nad4 inverted copies and the tRNA-Met appear to be transcribed on large polycistronic mRNAs. A model summarizing the events that would have occurred is proposed: (1) capture of the tRNA by the plasmid before its integration in the mtDNA or acquisition of the tRNA gene by recombination after the plasmid integration, (2) integration of the plasmid in the mtDNA, accompanied by a large duplication containing the nad4 gene and (3) erosion of the plasmid sequences by large deletions and mutations.