球孢白僵菌种内比较线粒体基因组学分析

【目的】明确球孢白僵菌种内线粒体基因组的分化程度。【方法】从GenBank下载已知的球孢白僵菌6个菌株线粒体基因组序列,详细分析基因组的组成结构,比较外显子区、内含子区和基因间区的碱基变异情况,分析菌株间的系统发育关系。【结果】球孢白僵菌不同菌株的线粒体基因组大小为28.8–32.3 kb,都有14个常见的核心蛋白编码基因、2个rRNA基因和25个tRNA基因,具有很强的共线性关系。但是,不同菌株含有的线粒体内含子数目存在差异(2–5个/菌株),在cox1、cox2和nad1基因中表现出内含子插入/缺失多态性,这是导致线粒体基因组大小变化的主要因素。对外显子、内含子和基因间区的碱基变异情况进行分析,发现内含子和基因间区相对变异较大,而外显子区相对变异较小。系统发育分析发现,这些球孢白僵菌菌株以很高的支持度聚在一起,具有相同内含子分布规律的菌株也具有较近的聚类关系。【结论】本研究首次报道球孢白僵菌因内含子数目不同、插入缺失突变和单核苷酸变异等在线粒体基因组上表现出较大程度的遗传分化,为认识真菌种内线粒体基因组分化提供了新的证据。     

中国地鼠线粒体基因组的序列分析与分子进化

目的 获得中国地鼠线粒体基因组序列,为线粒体疾病模型提供分子数据.方法 参照近缘物种的线粒体基因组序列,设计27对特异引物,采用TD-PCR及测序技术获得了中国地鼠的线粒体全基因组序列,分析了其基因组特点和各基因的定位.还结合GenBank中已发表的其他5种啮齿类动物的线粒体基因组序列,探讨啮齿类动物不同科间的系统进化关系.结果 中国地鼠线粒体基因组全长为16 283 bp,碱基组成为33.53％A、30.50％T、12.98％G、22.80％C,包括13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个非编码基因控制区.中国地鼠和金黄地鼠亲缘关系最近.结论 中国地鼠线粒体基因组各基因长度、位置与典型的啮齿类动物相似,其编码蛋白质区域和rRNA基因与其他啮齿类动物具有很高的同源性,显示线粒体基因组在进化上十分保守.5种动物的分子系统进化树与传统分类地位一致.     

池蝶蚌线粒体基因组全序列分析简

采用普通PCR扩增、SHOT-GUN测序、软件拼接首次获得了池蝶蚌(Hyriopsis schlegelii)线粒体基因组全序列。线粒体基因组全长为15939 bp,由13个蛋白质编码基因、22个tRNA基因、2个SrRNA基因和28个长度为1—393 bp的非编码区组成;除ND3-ND5、ND4L、ATP6、ATP8、COX1-COX3、tRNA-D、tRNA-H之外,其他大多数基因在L链编码。池蝶蚌线粒体全基因组序列、蛋白编码基因、tRNA基因、rRNA基因及非编码区的A+T含量分别为60.36%、59.84%、61.7%、60.23%及62.5%,与其他淡水蚌类一致,均表现出A+T偏好性,淡水蚌类线粒体基因组长度的差异主要表现在非编码区长度的差异。池蝶蚌mtDNA的COX2-12SrRNA区域基因排列存在差异,是ND3、tRNAHis、tRNAAla、tRNASer1、tRNASer2、tRNAGlu、ND2、tRNAMet 8个基因发生重组造成。22个tRNA基因都具有典型的三叶草二级结构,tRNA-E与tRNA-W间的非编码区含有一个ORF区,而控制区并未发现。从GenBank上下载的14种双壳纲贝类的mtDNA序列构建的系统进化树,显示池蝶蚌与三角帆蚌亲缘关系最近。研究结果为淡水珍珠蚌线粒体基因重排及进化特征提供理论依据。     

池蝶蚌线粒体基因组全序列分析

采用普通PCR扩增、SHOT-GUN测序、软件拼接首次获得了池蝶蚌（Hyriopsis schlegelii）线粒体基因组全序列。线粒体基因组全长为15939 bp,由13个蛋白质编码基因、22个tRNA基因、2个SrRNA基因和28个长度为1393 bp的非编码区组成;除ND3-ND5、ND4L、ATP6、ATP8、COX1-COX3、tRNA-D、tRNA-H之外,其他大多数基因在L链编码。池蝶蚌线粒体全基因组序列、蛋白编码基因、tRNA基因、rRNA基因及非编码区的A+T含量分别为60.36%、59.84%、61.7%、60.23%及62.5%,与其他淡水蚌类一致,均表现出A+T偏好性,淡水蚌类线粒体基因组长度的差异主要表现在非编码区长度的差异。池蝶蚌mtDNA的COX2-12SrRNA区域基因排列存在差异,是ND3、tRNAHis、tRNAAla、tRNASer1、tRNASer2、tRNAGlu、ND2、tRNAMet 8个基因发生重组造成。22个tRNA基因都具有典型的三叶草二级结构,tRNA-E与 tRNA-W间的非编码区含有一个ORF区,而控制区并未发现。从GenBank上下载的14种双壳纲贝类的mtDNA序列构建的系统进化树,显示池蝶蚌与三角帆蚌亲缘关系最近。研究结果为淡水珍珠蚌线粒体基因重排及进化特征提供理论依据。       

烟草棒状弯孢菌线粒体全基因组特征及系统发育分析

近年来,由弯孢属真菌侵染引发的病害在烟草上有上升的趋势,严重影响烟叶的产量和质量。为了更好地防治由弯孢属真菌引起的烟草叶斑病,本研究利用高通量测序技术对一株分离自烟草叶片的棒状弯孢菌Curvulariaclavata线粒体基因组进行测序,组装得到一个环状的线粒体基因组,并对其组成特征、与典型叶斑病真菌的系统发育关系进行分析。结果表明,烟草棒状弯孢菌线粒体基因组长度为41 763 bp,共编码38个基因(13个蛋白编码基因、2个rRNA基因和23个tRNA基因),其碱基组成有显著的A-T偏好性,占比高达70.35%。线粒体基因组中只有3个内含子和少量重复序列,这是造成其基因组大小收缩的主要原因。通过6个近缘病原真菌线粒体全基因的共线性分析,发现其线粒体基因组发生了基因重排事件。同时,物种同源区长度与对应物种的线粒体基因组大小呈正相关关系,同源区长度可能会影响物种的线粒体基因组大小。在选择压力分析中,发现烟草棒状弯孢菌线粒体为确保优势基因稳定遗传,自然选择和纯化选择起到了主导作用。系统发育分析表明烟草棒状弯孢菌与麦根腐平脐蠕孢Bipolarissorokiniana和稻平脐蠕孢Bipola...     

缅甸陆龟线粒体全基因组的测序及分析

本文参照近缘物种的线粒体基因组序列,设计17对特异引物,采用LD-PCR、PCR及测序技术获得了我国广西产缅甸陆龟的线粒体全基因组序列,分析了其基因组特点和各基因的定位。结果表明:缅甸陆龟线粒体基因组全长为16813bp,碱基组成为35.30%A、26.47%T、12.09%G、26.14%C,包括13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个非编码基因控制区(D-Loop区)。缅甸陆龟线粒体基因组各基因长度、位置与典型的脊椎动物相似,其编码蛋白质区域和rRNA基因与其它脊椎动物具有很高的同源性,显示龟类线粒体基因组在进化上十分保守。将缅甸陆龟的线粒体基因组序列提交到GenBank,获得的检索号为DQ656607。本文还结合GenBank中已发表的其它16种龟鳖类动物的线粒体基因组序列,探讨龟鳖类动物不同科间的系统进化关系。     

北京鸭线粒体基因组全序列测定和分析

线粒体DNA作为遗传标记,已在家鸡(Gallus gallus)和家鹅(Anser anser)的研究中取得了重大进展,而对家鸭(Anas platyrhychos domesticus)的研究却很少.本研究参照近源物种线粒体基因组序列设计15对引物,通过PCR扩增、测序、拼接,获得北京鸭(A.platyrhychos)线粒体基因组全序列,初步分析其特点和各基因的定位.结果显示,北京鸭线粒体基因组全长16 604 bp,碱基组成为29.19%A、22.20%T、15.80%G、32.81%C,包含13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个非编码控制区(D-loop),基因组成及排列顺序与其他鸟类相似.基于线粒体D-loop区全序列,用N-J法构建了7种雁形目鸟类系统进化树,结果表明,北京鸭与绿头鸭(A.platyrhychos)系统进化关系较近.     

大紫蛱蝶线粒体基因组全序列分析

通过PCR步移法对大紫蛱蝶Sasakia charonda coreana线粒体基因组全序列进行了测定和分析。分析结果表明:大紫蛱蝶线粒体基因组全长15233bp,包括13个蛋白编码基因、22个tRNA基因、2个rRNA基因以及长度为381bp的非编码区。A、T、C、G碱基含量分别为39.7%、40.2%、12.2%、7.9%。9个蛋白编码基因和14个tRNA基因在J链编码,其余4个蛋白编码基因和8个tRNA基因在N链编码,基因排列顺序与其它已知鳞翅目昆虫相同。13个蛋白编码基因中除COⅠ以CGA作为起始密码外,其余蛋白质基因均以ATN作为起始密码子,终止密码子多数为典型的TAA、TAG,只有COⅡ和ND4以单独的T作为终止密码子。在所测得的22个tRNA基因中,除tRNA Ser(AGN)缺少DHU臂外,其余tRNA均能形成典型的三叶草结构。与其它多数鳞翅目昆虫一样,大紫蛱蝶的非编码区序列中散在着一些长短不一的串联重复单元,在与其近缘物种非编码区的比较当中并未发现共同的保守序列区。     

球孢白僵菌羧基转运蛋白基因BbJEN1及其上游序列的克隆与分析

在分析一株球孢白僵菌TDNA插入突变体T12的Tagging序列的基础上,根据与其具有高度同源性的一条金龟子绿僵菌EST序列（编号为AJ273226）设计简并引物,用YADE法从球孢白僵菌中扩增出该EST的同源序列及其延伸序列。序列分析表明,该片段与粗糙脉孢霉的羧基转运蛋白JEN1具有高度同源性,由此确定该序列为球孢白僵菌羧基转运蛋白JEN1基因的部分序列。然后利用YADE法延伸扩增该序列的上、下游序列,获得球孢白僵菌羧基转运蛋白JEN1的全长DNA序列,命名为GBbJEN1。利用3′RACE扩增出球孢白僵菌羧基转运蛋白JEN1的cDNA序列,命名为BbJEN1。BbJEN1全长1656bp,编码514个氨基酸的蛋白。推测蛋白分子量为55975.37Da,等电点9.32。氨基酸序列与金龟子绿僵菌、粗糙脉孢霉和酿酒酵母羧基转运蛋白JEN1的同源性分别为77%、66%和30%。序列分析表明,GBbJEN1含有2个内含子。Southern杂交表明,GBbJEN1基因在球孢白僵菌基因组中为单拷贝。利用RTPCR法对BbJEN1的表达特性进行了分析,结果发现BbJEN1基因的转录受蟑螂壳、蝉蜕等昆虫体壁的诱导,受葡萄糖的抑制。进一步利用YADE法获得了长为977bp的GBbJEN1上游序列,其中含有可能的葡萄糖抑制调控序列和压力反应元件。     

子囊菌较担子菌具有更快的进化速率和更高的物种多样性

研究表明, 在一些进化分支或有机体之间存在着核苷酸或氨基酸替代速率差异. 越来越多的证据表明, 种群内的中性分子突变与物种多样化相关. 超过98%的陆生真菌属于子囊菌门和担子菌门, 而且前者的物种多样性明显多于后者. 获得了地衣型真菌红脐鳞的21种蛋白编码基因序列, 并应用这些及GenBank中的相关序列进行了随后的分析. 建立了3组矩阵: (1) 13种真菌, 包括105种蛋白编码基因; (2) 9种真菌, 包括21种蛋白编码基因; (3) 299种真菌的nu LSU rDNA序列. 应用这些数据, 检测了子囊菌门与担子菌门以及子囊菌内部主要纲之间的基因替代速率. 蛋白质数据和nu LSU rDNA数据分析显示, 子囊菌的基因替代速率显著快于担子菌; 而且在子囊菌内部, 物种丰富的粪壳菌纲进化速率最快, 物种数量较少的锤舌菌纲进化最慢. 结果提示, 子囊菌的快速进化不是得益于互惠共生、生态条件、无性繁殖、代谢速率或者短世代时间, 而可能是由奠基者效应引起的. 这是物种数量与进化速率相关的又一证据, 与奠基者效应是导致物种丰富的分支进化速率较快的主要原因的假说相吻合.     

暗纹东方鲀线粒体基因组核苷酸全序列测定与分析

以暗纹东方鲀(Takifugu fasciatus)肝的线粒体DNA为模板,参照红鳍东方鲀(T.rubripes)等近源鱼类的线粒体基因组DNA序列,设计合成14对特异引物,进行PCR扩增并测序,首次获得了暗纹东方鲀线粒体基因组全序列。结果表明,暗纹东方鲀线粒体基因组序列全长16 444 bp(GenBank登录号为GQ409967),A+T含量为55.8%,其mtDNA结构与其他脊椎动物相似,由22个tRNA基因、2个rRNA基因、13个蛋白质编码基因和1段819 bp非编码的控制区(D-loop)所组成。蛋白质基因除COⅠ和ND6的起始密码子为GTG、CCT以外,均为典型的起始密码子ATG。ND1、ATPase8、COⅢ、ND4L、ND5、Cyt b使用典型的终止密码子TAA,其他的使用不完全终止密码子。除ND6和tRNAGln、tRNAAla、tRNAAsn、tRNACys、tRNATyr、tRNASer、tRNAGlu、tRNAPro在L-链上编码之外,其余基因均在H-链编码。基因排列顺序与已测定的鲀类一致,这显示了鲀类线粒体基因排列顺序上的保守性。tRNA基因核苷酸长度为64～73nt,预测了22个tRNA基因的二级结构,均呈较为典型的三叶草状。基于19种鲀类mtDNA全序列构建的进化树表明,暗纹东方鲀与红鳍东方鲀、中华东方鲀(T.chinensis)聚成一个姊妹群。结果还支持东方鲀属鱼类为一单系类群。     

Characterization of mitochondrial genome of Formosan sambar (Rusa unicolor swinhoei)

The complete mitochondrial genome sequence of the Formosan sambar (Rusa unicolor swinhoei) was obtained by DNA sequencing based on PCR fragments amplified by 26 primer pairs designed by ourselves. The results indicated that the mtDNA is 16,505 bp in size. This is the first report on mitochondrial DNA (mtDNA) sequence analysis of the Formosan sambar and the sequence was deposited in the GenBank database under the accession number DQ989636. The complete mitochondrial sequence included the following gene sequences: 12S and 16S rRNAs, 22 tRNAs and 13 protein-coding genes. The base composition of the sequence was as follows: A, 33.51%; T, 28.97%; C, 24.07%; and G, 13.46%. The mitochondrial D-loop region was also analyzed for comparative purposes in the Formosan sambar and 13 other species within the Cervidae family using neighbour-joining method. The phylogenetic tree demonstrated that there are two separate groups, a European type and an Asian type, within the Cervidae family. The D-loop sequences of mtDNA of 24 Formosan sambar animals were compared, and the results showed that the Formosan sambar can be divided into two clades.     

Unusual mitochondrial genome structure of the freshwater goby Odontobutis platycephala: rearrangement of tRNAs and an additional non-coding region

Mitochondrial DNA was isolated from the Korean freshwater gobioid fish Odontobutis platycephala by long-polymerase chain reaction with conserved primers and this mtDNA was sequenced by primer walking using flanking sequences as sequencing primers. The resultant O. platycephala mtDNA sequence was found to be 17 588 bp in size with a mostly conserved structural organization when compared with that of other teleost fish. Rearrangements of tRNAs (tRNA-Ser, tRNA-Leu, tRNA-His) and an additional non-coding region (533 bp) were present between the ND4 and ND5 genes. In the present paper, the basic characteristics of the O. platycephala mitochondrial genome is reported, including its structural organization, base composition of rRNAs, tRNAs and protein-encoding genes, characteristics of mitochondrial tRNAs and the peculiar rearrangement features of some parts of the mtDNA. Phylogenetic analysis performed using the cytochrome b gene sequences of 16 Korean freshwater fishes (15 gobioids) with the Bayesian algorithm showed that O. platycephala forms a clade (1·00 of posterior probability) with other species of Odontobutis . This suggests that the observed rearrangement between the ND4 and ND5 genes in the O. platycephala mitogenome reflects independent events.     

Complete DNA Sequence of the Mitochondrial Genome of the Black Chiton, Katharina Tunicata

The DNA sequence of the 15,532-base pair (bp) mitochondrial DNA (mtDNA) of the chiton Katharina tunicata has been determined. The 37 genes typical of metazoan mtDNA are present: 13 for protein subunits involved in oxidative phosphorylation, 2 for rRNAs and 22 for tRNAs. The gene arrangement resembles those of arthropods much more than that of another mollusc, the bivalve Mytilus edulis. Most genes abut directly or overlap, and abbreviated stop codons are inferred for four genes. Four junctions between adjacent pairs of protein genes lack intervening tRNA genes; however, at each of these junctions there is a sequence immediately adjacent to the start codon of the downstream gene that is capable of forming a stem-and-loop structure. Analysis of the tRNA gene sequences suggests that the D arm is unpaired in tRNA(ser(AGN)), which is typical of metazoan mtDNAs, and also in tRNA(ser(UCN)), a condition found previously only in nematode mtDNAs. There are two additional sequences in Katharina mtDNA that can be folded into structures resembling tRNAs; whether these are functional genes is unknown. All possible codons except the stop codons TAA and TAG are used in the protein-encoding genes, and Katharina mtDNA appears to use the same variation of the mitochondrial genetic code that is used in Drosophila and Mytilus. Translation initiates at the codons ATG, ATA and GTG. A + T richness appears to have affected codon usage patterns and, perhaps, the amino acid composition of the encoded proteins. A 142-bp non-coding region between tRNA(glu) and CO3 contains a 72-bp tract of alternating A and T.     

Complete Mitochondrial DNA Sequence of the Scallop <Emphasis Type="Italic">Placopecten magellanicus</Emphasis>: Evidence of Transposition Leading to an Uncharacteristically Large Mitochondrial Genome

Complete sequence determination of the mitochondrial (mt) genome of the sea scallop Placopecten magellanicus reveals a molecule radically different from that of the standard metazoan. With a minimum length of 30,680 nucleotides (nt; with one copy of a 1.4 kilobase (kb) repeat) and a maximum of 40,725 nt, it is the longest reported metazoan mitochondrial DNA (mtDNA). More than 50% of the genome is noncoding (NC), consisting of dispersed, imperfectly repeated sequences that are associated with tRNAs or tRNA-like structures. Although the genes for atp8 and two tRNAs were not discovered, the genome still has the potential for encoding 46 genes (the additional genes are all tRNAs), 9 of which encode tRNAs for methionine. The coding portions appear to be evolving at a rate consistent with other members of the pectinid clade. When the NC regions containing “dispersed repeat families” are examined in detail, we reach the conclusion that transposition involving tRNAs or tRNA-like structures is occurring and is responsible for the large size and abundance of noncoding DNA in the molecule. The rarity of enlarged mt genomes in the face of a demonstration that they can exist suggests that a small, compact organization is an actively maintained feature of metazoan mtDNA. Reviewing Editor: Gail Simmons     

Mitochondrial DNA in the sea urchin Arbacia lixula: evolutionary inferences from nucleotide sequence analysis.

From the stirodont Arbacia lixula we determined the sequence of 5,127 nucleotides of mitochondrial DNA (mtDNA) encompassing 18 tRNAs, two complete coding genes, parts of three other coding genes, and part of the 12S ribosomal RNA (rRNA). The sequence confirms that the organization of mtDNA is conserved within echinoids. Furthermore, it underlines the following peculiar features of sea urchin mtDNA: the clustering of tRNAs, the short noncoding regulatory sequence, and the separation by the ND1 and ND2 genes of the two rRNA genes. Comparison with the orthologous sequences from the camarodont species Paracentrotus lividus and Strongylocentrotus purpuratus revealed that (1) echinoids have an extra piece on the amino terminus of the ND5 gene that is probably the remnant of an old leucine tRNA gene; (2) third-position codon nucleotide usage has diverged between A. lixula and the camarodont species to a significant extent, implying different directional mutational pressures; and (3) the stirodont-camarodont divergence occurred twice as long ago as did the P. lividus-S. purpuratus divergence.     

Mitochondrial tRNAs as light strand replication origins: Similarity between anticodon loops and the loop of the light strand replication origin predicts initiation of DNA replication

Stem-loop hairpins formed by mitochondrial light strand replication origins (OL) and by heavy strand DNA coding for tRNAs that form OL-like structures initiate mitochondrial replication. The loops are recognized by one of the two active sites of the vertebrate mitochondrial gamma polymerase, which are homologuous to the active sites of class II amino-acyl tRNA synthetases. Therefore, the polymerase site recognizing the OL loop could recognize tRNA anticodon loops and sequence similarity between anticodon and OL loops should predict initiation of DNA replication at tRNAs. Strengths of genome-wide deamination gradients starting at tRNA genes estimate extents by which replication starts at that tRNA. Deaminations (A→G and C→T) occur proportionally to time spent single stranded by heavy strand DNA during mitochondrial light strand replication. Results show that deamination gradients starting at tRNAs are proportional to sequence similarity between OL and tRNA loops: most for anticodon-, least D-, intermediate for TψC-loops, paralleling tRNA synthetase recognition interactions with these tRNA loops. Structural and sequence similarities with regular OLs predict OL function, loop similarity is dominant in most tRNAs. Analyses of sequence similarity and structure independently substantiate that DNA sequences coding for mitochondrial tRNAs sometimes function as alternative OLs. Pathogenic mutations in anticodon loops increase similarity with the human OL loop, non-pathogenic polymorphisms do not. Similarity/homology alignment hypotheses are experimentally testable in this system.     

Comparative Analysis of Mitochondrial Genomes in <Emphasis Type="Italic">Bombina</Emphasis> (Anura; Bombinatoridae)

The complete mitochondrial genomes of two basal anurans, Bombina bombina and B. variegata (Anura; Bombinatoridae), were sequenced. The gene order of their mitochondrial DNA (mtDNA) is identical to that of canonical vertebrate mtDNA. In contrast, we show that there are structural differences in regulatory regions and protein coding genes between the mtDNA of these two closely related species. Corrected sequence divergence between the mtDNA of B. bombina and B. variegata amounts to 8.7% (2.3% divergence in amino acids). Comparisons with two East Asian congeners show that the control region contains two repeat regions, LV1 and LV2, present in all species except for B. bombina, in which LV2 has been secondarily lost. The rRNAs and tRNAs are characterized by low nucleotide divergence. The protein coding genes are considerably more disparate, although functional constraint is high but variable among genes, as evidenced by dN/dS ratios. A mtDNA phylogeny established the distribution of autapomorphic nonsynonomous substitutions in the mitogenomes of B. bombina and B. variegata. Nine of 98 nonsynonomous substitutions led to radical amino acid replacements that may alter mitochondrial protein function. Most radical substitutions were found in ND2, ND4, or ND5, encoding mitochondrial subunits of complex I of the electron transport system. The extensive divergence between the mitogenomes of B. bombina and B. variegata is discussed in terms of its possible role in impeding gene flow in natural hybrid zones between these two species.     

桔小实蝇线粒体基因组全序列及其分析

桔小实蝇Bactrocera dorsalis线粒体基因组全序列对研究实蝇分子系统进化具有重要意义。本研究通过DNA测序和克隆技术,对桔小实蝇mtDNA全序列进行了测定和分析。结果表明：桔小实蝇线粒体基因组全长15 915 bp（GenBank序列号: DQ845759）。基因组碱基组成为39.3%A,16.2%C,10.2%G,34.3%T,由13个蛋白编码基因、22个tRNA基因、2个rRNA基因以及一个非编码的控制区域（A+T-rich区）组成。7个蛋白编码基因和13个tRNA基因从J链编码,其余6个蛋白编码基因和9个tRNA基因从N链编码。位于J链上的蛋白编码基因具有近似的A、T含量,而位于N链上的蛋白编码基因的A的含量明显高于T的含量。以mtDNA COⅠ基因为例,比较了桔小实蝇与其他14种实蝇的亲缘关系,结果显示其与同亚属（果实蝇亚属Bactrocera）内的其他近缘种相互间的同源性很高。