Sequencing and alignment of mitochondrial genomes of Tibetan chicken and two lowland chicken breeds

Tibetan chicken lives in high-altitude area and has adapted well to hypoxia genetically. Shouguang chicken and Silky chicken are both lowland chicken breeds. In the present study, the complete mito-chondrial genome sequences of the three chicken breeds were all sequenced. The results showed that the mitochondrial DNAs (mtDNAs) of Shouguang chicken and Silky chicken consist of 16784 bp and 16785 bp respectively, and Tibetan chicken mitochondrial genome varies from 16784 bp to 16786 bp. After sequence analysis, 120 mutations, including 4 single nucleotide polymorphisms (SNPs) in tRNA genes, 9 SNPs and 1 insertion in rRNA genes, 38 SNPs and 1 deletion in D-LOOP, 66 SNPs in pro-tein-coding genes, were found. This work will provide clues for the future study on the association between mitochondrial genes and the adaptation to hypoxia.Tibetan chicken, lowland chicken, mitochondrial genome, hypoxia.     

Complete sequence of the Tibetan Mastiff mitochondrial genome and its phylogenetic relationship with other Canids ( Canis, Canidae)

In this study, the complete sequence of the Tibetan Mastiff mitochondrial genome (mtDNA) was determined, and the phylogenetic relationships between the Tibetan Mastiff and other species of Canidae were analyzed using the coyote (Canis latrans) as an outgroup. The complete nucleotide sequence of the Tibetan Mastiff mtDNA was 16 710 bp, and included 22 tRNA genes, 2S rRNA gene, 13 protein-coding genes and one non-coding region (D-loop region), which is similar to other mammalian mitochondrial genomes. The characteristics of the protein-coding genes, non-coding region, tRNA and rRNA genes among Canidae were analyzed in detail. Neighbor-joining and maximum-parsimony trees of Canids constructed using 12 mitochondrial protein-coding genes showed that as the coyotes and Tibetan wolves clustered together, so too did the gray wolves and domestic dogs, suggesting that the Tibetan Mastiff originated from the gray wolf as did other domestic dogs. Domestic dogs clustered into four clades, implying at least four maternal origins (A to D). The Tibetan Mastiff, which belongs to clade A, appears to be closely related to the Saint Bernard and the Old English Sheepdog.     

双壳贝类线粒体基因组结构的比较

利用比较基因组学和生物信息学方法, 比较分析了已登录到GenBank中的14种海产双壳贝类和2种淡水双壳贝类的线粒体基因组的结构特征。结果发现, 双壳贝类线粒体的基因组结构、基因排列顺序均互不相同; 不同目、科和属之间线粒体基因组的大小、基因排列方式以及基因种类也存在明显的差异, 尤其是基因排列方式没有明显的规律。对16种双壳贝类的线粒体基因组全序列、编码基因序列进行系统分析, 分别得到了不同的聚类结果, 即用基因组全序列聚类时, 16种贝类的聚类结果与传统的形态学分类地位基本相同; 而将16种贝类的所有蛋白质编码基因和2个rRNA基因按照一致顺序排列起来进行聚类时, 所得的系统分类情况与这些贝类传统的形态学分类地位相差较大。     

植绥螨科线粒体基因组研究进展

植绥螨科属于囊螨总科,大部分植绥螨为害螨、害虫的重要天敌,在农业生产上具有重要的应用价值。其线粒体基因组具有独特特征,引起了生物学家的广泛关注。本文就植绥螨科线粒体基因组的结构、非编码区、碱基组成、基因重排和tRNA的特征进行综述,其特征有：（1）植绥螨科中发现了螯肢动物最大的线粒体基因组;（2）植绥螨科线粒体基因组非编码区的AT含量差异大,编码区的AT含量差异小;（3）植绥螨科线粒体基因组均发生了不同程度的的基因重排;（4）已测定的植绥螨科部分物种tRNA基因二级结构出现了截短和碱基错配的现象,部分物种的线粒体基因组出现反密码子突变的情况。在今后的研究中应进一步测定植绥螨科关键类群的线粒体基因组,深入分析植绥螨科出现大量基因重排的原因,以期能反映植绥螨科的真实进化历程。     

The origin and genetic diversity of Chinese native chicken breeds

The first 539 bases of mitochondrial DNA D-loop region of six Chinese native chicken breeds (Gallus gallus domesticus) were sequenced and compared to those of the red junglefowl (Gallus gallus), the gray junglefowl (Gallus sonneratii), the green junglefowl (Gallus varius) and Lafayette's junglefowl (Gallus lafayettei) reported in GenBank, and the phylogenetic trees for the chickens were constructed based on the D-loop sequences. The results showed that the four species of the genus Gallus had great differences among each other, the G. g. domesticus was closest to the red junglefowl in Thailand and its adjacent regions, suggesting the Chinese domestic fowl probably originated from the red junglefowl in these regions. The two subs pecies of Thailand, G. g. gallus and G. g. spadiceus, should belong to one subspecies because of their resemblance. In the case of native breeds, there existed a great difference between the egg breeds and general purpose breeds, which suggested different maternal origins of the two types.     

藏羚羊肌红蛋白(MGB)基因编码区的克隆与分析

为了探讨藏羚羊低氧适应的分子生物学机制,从藏羚羊(Pantholops hodgsonii)骨骼肌组织中提取总RNA,通过逆转录聚合酶联反应(RT-PCR)技术扩增出MGB基因编码区cDNA片段,并与pGEM-T Easy载体连接构建重组质粒,转化DH5α菌。扩增培养后鉴定阳性质粒并进行序列测定,结果与NCBI数据库进行比较。结果显示,MGB基因编码区由465bp组成,编码154个氨基酸。其序列与绵羊、牛、猪、人、小鼠、大鼠的同源性分别是98%、97%、90%、86%、82%、81%。推测出的氨基酸序列与绵羊、牛有98%同源性,而与猪、人、小鼠及大鼠分别有89%、85%、80%、79%的同源性。与NCBI数据库登录的绵羊的MGB cDNA序列比较发现,藏羚羊MGB基因的21位和78位密码子分别发生了突变(GGT→GAT和GAA→AAG),其对应的氨基酸分别由甘氨酸变为天冬氨酸及谷氨酸变为赖氨酸。至此,成功克隆出藏羚羊MGB基因编码区,为进一步揭示藏羚羊低氧适应的分子机制打下基础。     

One-step PCR amplification of complete arthropod mitochondrial genomes

A new PCR primer set which enables one-step amplification of complete arthropod mitochondrial genomes was designed from two conserved 16S rDNA regions for the long PCR technique. For this purpose, partial 16S rDNAs amplified with universal primers 16SA and 16SB were newly sequenced from six representative arthropods: Armadillidium vulgare and Macrobrachium nipponense (Crustacea), Anopheles sinensis (Insecta), Lithobius forficatus and Megaphyllum sp. (Myriapoda), and Limulus polyphemus (Chelicerata). The genomic locations of two new primers, HPK16Saa and HPK16Sbb, correspond to positions 13314-13345 and 12951-12984, respectively, in the Drosophila yakuba mitochondrial genome. The usefulness of the primer set was experimentally examined and confirmed with five of the representative arthropods, except for A. vulgare, which has a linearized mitochondrial genome. With this set, therefore, we could easily and rapidly amplify complete mitochondrial genomes with small amounts of arthropod DNA. Although the primers suggested here were examined only with arthropod groups, a possibility of successful application to other invertebrates is very high, since the high degree of sequence conservation is shown on the primer sites in other invertebrates. Thus, this primer set can serve various research fields, such as molecular evolution, population genetics, and molecular phylogenetics based on DNA sequences, RFLP, and gene rearrangement of mitochondrial genomes in arthropods and other invertebrates.     

山鹧鸪属鸟类线粒体基因组的比较及系统发育研究

海南山鹧鸪(Arborophila ardens)对生境选择比较严格,种群数量稀少,属于濒危物种。为进一步研究山鹧鸪属的进化和系统发育关系,文章利用Illumina Hiseq2000高通量测序技术获得了海南山鹧鸪线粒体全基因组序列,从比较基因组学角度分析了4种山鹧鸪鸟类的线粒体基因组特征,并探讨了山鹧鸪属鸟类的系统发育地位。研究结果表明：(1) 海南山鹧鸪线粒体基因组长度为16 730 bp,编码13个蛋白质编码基因、2个核糖体RNA基因、22个转运RNA基因以及1个控制区;(2) 山鹧鸪属物种受到了纯化选择的作用,且在进化过程中积累了更多的非同义替换;(3) 山鹧鸪属位于雉科鸟类系统树的基部位置,其中白眉山鹧鸪与红喉山鹧鸪互为姐妹群,海南山鹧鸪位于山鹧鸪属的基部位置,与其他3种山鹧鸪鸟类的亲缘关系较远。     

两种毛蚜线粒体基因组比较分析

【目的】线粒体基因组分析已被应用于昆虫系统发育研究。本研究以蚜科Aphididae重要类群毛蚜亚科物种为代表,测定并比较分析了该类蚜虫的线粒体基因组特征,探讨了基于线粒体基因组信息的蚜虫系统发育关系重建。【方法】以毛蚜亚科三角枫多态毛蚜Periphyllus acerihabitans Zhang和针茅小毛蚜Chaetosiphella stipae Hille Ris Lambers,1947为研究对象,利用长短PCR相结合的方法测定线粒体基因组的序列,分析了基因组的基本特征;基于在线t RNAscan-SE Search Server搜索方法预测了t RNA的二级结构;基于12个物种(本研究获得的2个物种和10个Gen Bank上下载的物种数据)的蛋白编码基因(PCGs)序列,利用最大似然法和贝叶斯法重建了蚜科的系统发育关系。【结果】两种毛蚜均获得了约94%的线粒体基因组数据,P.acerihabitans获得了14 908 bp,控制区为1 205 bp;C.stipae获得了13 893 bp,控制区为609 bp。两种毛蚜同时获得33个基因,包含接近完整的13个蛋白编码基因(PCGs)(nad5不完整),18个tRNA,2个rRNA基因;ka/ks值表明,C.stipae的进化速率更快。从基因组组成、基因排列顺序、核苷酸组成分析、密码子使用情况、t RNA二级结构等特征来分析,两种蚜虫线粒体基因组基本特征相似。系统发育重建结果表明毛蚜亚科、蚜亚科的单系性得到了支持,毛蚜亚科位于蚜科的基部位置。【结论】两种毛蚜线粒体基因组的基本特征相似,符合蚜虫线粒体基因组的一般特征,两种线粒体基因组的长度差异主要来自控制区长度的不同;系统发育重建支持毛蚜亚科与蚜亚科的单系性,毛蚜亚科位于蚜科较为基部的位置。研究结果为蚜虫类系统发育重建提供了参考。     

Codon usage and bias in mitochondrial genomes of parasitic platyhelminthes

Sequences of the complete protein-coding portions of the mitochondrial (mt) genome were analysed for 6 species of cestodes (including hydatid tapeworms and the pork tapeworm) and 5 species of trematodes (blood flukes and liver- and lung-flukes). A near-complete sequence was also available for an additional trematode (the blood fluke Schistosoma malayensis). All of these parasites belong to a large flatworm taxon named the Neodermata. Considerable variation was found in the base composition of the protein-coding genes among these neodermatans. This variation was reflected in statistically-significant differences in numbers of each inferred amino acid between many pairs of species. Both convergence and divergence in nucleotide, and hence amino acid, composition was noted among groups within the Neodermata. Considerable variation in skew (unequal representation of complementary bases on the same strand) was found among the species studied. A pattern is thus emerging of diversity in the mt genome in neodermatans that may cast light on evolution of mt genomes generally.     

节肢动物线粒体基因组碱基组成特征分析

利用93个节肢动物线粒体基因组数据,分析了线粒体基因组的碱基组成,及对氨基酸组成的影响。研究表明:(1)节肢动物线粒体基因组GC含量较低,分布范围较窄(13.28%～39.64%)。基因组GC含量与密码子第三位置的GC含量间的相关性(r=0.9432,p<0.01)比密码子第一、二位置上的相关性强。(2)在密码子的三个不同位置上均可以观察到C<->T和A<->G相互取代的现象。(3)从NC.004529和NC.003979两个序列的对比研究中可以发现碱基组成变化会引起氨基酸组成的变化,这种变化不仅体现在不同的物种之间,而且也体现在同一基因组内部的不同基因之间,这些影响可能是相互的。表明节肢动物线粒体基因组中的碱基变化是受多种因素共同作用的结果。     

直翅目昆虫线粒体基因组研究进展

本文总结了本实验室对40余种直翅目昆虫的线粒体基因组序列的研究方法和主要结果.直翅目线粒体基因组研究中最重要的发现包括：（1）在直翅目昆虫线粒体基因组中发现了3种基因排列次序.蝗亚目除蜢总科外都具有DK排列.蜢总科的变色乌蜢为KD 排列,与蝗亚目其他总科不同,而与螽亚目昆虫的排序方式相同.已测出的螽亚目大多数昆虫的KD 排列顺序与典型节肢动物的完全相同,但在黄脸油葫芦Teleogryllus emma发生了tRNA^Glu,tRNA^Ser和tRNA^Asn的倒置;（2）在疑钩额螽Ruspolia dubia中发现了一种到目前为止具有最短控制区（70 bp）的线粒体基因组;（3）采用多种方法分析了昆虫A+T富集区存在的调控序列和二级结构特征,获得了昆虫A+T富集区保守序列的一致结构.采用Z曲线分析蝗虫的A+T富集区,表明也存在与原核生物复制起点类似的信号;（4）构建了30种蝗虫12S rRNA和16S rRNA的二级结构.在昆虫线粒体基因组非编码链中发现了一些类tRNA结构和tRNA异构体;（5）构建了基于线粒体基因组数据的直翅目昆虫主要亚科以上分类单元之间的系统发育关系.     

藏鸡线粒体全基因组序列的测定和分析

通过PCR扩增,测序,拼接,获得藏鸡（Tibetan Chicken）线粒体全基因组序列并进行数据分析处理。藏鸡线粒体全基因组序列全长16783bp,共有13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个D-loop区。模拟电子酶切结果显示,藏鸡DraI酶的酶切结果和先前报道的原鸡,茶花鸡,尼西鸡和大理漾濞黄鸡的酶切结果都不相同,为藏鸡特有。基于D-loop区全序列和13个蛋白质编码基因序列,采用N-J算法与原鸡属4个种,3个亚种和3个家鸡品系构建系统进化树：初步确定藏鸡起源于红原鸡,与家鸡中的来航鸡、白洛克鸡亲缘关系最近,但是藏鸡的进化与来航鸡、白洛克鸡这两个家鸡品系又显得相对独立。推测可能原因是藏鸡的祖先在进入高原以后处于相对封闭的环境,从而形成了独特群体遗传特性。     

Origin of Hungarian indigenous chicken breeds inferred from mitochondrial DNA D-loop sequences

In this study, we assessed the maternal origin of six Hungarian indigenous chicken breeds using mitochondrial DNA information. Sequences of Hungarian chickens were compared with the D-loop chicken sequences annotated in the GenBank and to nine previously described reference haplotypes representing the main haplogroups of chicken. The first 530 bases of the D-loop region were sequenced in 74 chickens of nine populations. Eleven haplotypes (HIC1-HIC11) were observed from 17 variable sites. Three sequences (HIC3, HIC8 and HIC9) of our chickens were found as unique to Hungary when searched against the NCBI GenBank database. Hungarian domestic chicken mtDNA sequences could be assigned into three clades and probably two maternal lineages. Results indicated that 86% of the Hungarian haplotypes are related to the reference sequence that likely originated from the Indian subcontinent, while the minor part of our sequences presumably derive from South East Asia, China and Japan.     

Characterization of four mitochondrial genomes of Crambidae (Lepidoptera,Pyraloidea) and phylogenetic implications

Loxostege turbidalis, Loxostege aeruginalis, Pyrausta despicata, and Crambus perlellus belong to Crambidae, Pyraloidea. Their mitochondrial genomes (mitogenomes) were successfully sequenced. The mitogenomes of L. turbidalis, L. aeruginalis, P. despicata, and C. perlellus are 15 240 bp, 15 339 bp, 15 389 bp, and 15 440 bp. The four mitogenomes all have a typical insect mitochondrial gene order, including 13 protein-coding genes (PCGs), 22 transfer RNA (tRNA) genes, two ribosomal RNA (rRNA) genes, and one A + T rich region (control region). The PCGs are initiated by the typical ATN codons, except CGA for the cox1 gene. Most PCGs terminate with common codon TAA or TAG, the incomplete codon T is found as the stop codon for cox2, nad4, and nad5. Most tRNA genes exhibit typical cloverleaf structure, except trnS1 (AGN) lacking the dihydrouridine (DHU) arm. The secondary structure of rRNA of four mitogenomes were predicted. Poly-T structure and micro-satellite regions are conserved in control regions. The phylogenetic analyses based on 13 PCGs showed the relationships of subfamilies in Pyraloidea. Pyralidae, and Crambidae are monophyletic, respectively. Pyralidae comprises four subfamilies, which form the following topology with high support values: (Galleriinae + ((Pyralinae + Epipaschiinae)+ Phycitinae)). Crambidae includes seven subfamilies and is divided into two lineages. Pyraustinae and Spilomelinae are sister groups of each other, and form the “PS clade.” Other five subfamilies (Crambinae, Acentropinae, Scopariinae, Schoenobiinae, and Glaphyriinae) form the “non-PS clade” in the Bayesian inference tree. However, Schoenobiinae is not grouped with the other four subfamilies and located at the base of Crambidae in two maximum likelihood trees.     

Long-term conservation of six duplicated structural genes in cephalopod mitochondrial genomes

The complete nucleotide sequences of the mitochondrial (mt) genomes of three cephalopods, Octopus vulgaris (Octopodiformes, Octopoda, Incirrata), Todarodes pacificus (Decapodiformes, Oegopsida, Ommastrephidae), and Watasenia scintillans (Decapodiformes, Oegopsida, Enoploteuthidae), were determined. These three mt genomes encode the standard set of metazoan mt genes. However, W. scintillans and T. pacificus mt genomes share duplications of the longest noncoding region, three cytochrome oxidase subunit genes and two ATP synthase subunit genes, and the tRNA(Asp) gene. Southern hybridization analysis of the W. scintillans mt genome shows that this single genome carries both duplicated regions. The near-identical sequence of the duplicates suggests that there are certain concerted evolutionary mechanisms, at least in cephalopod mitochondria. Molecular phylogenetic analyses of mt protein genes are suggestive, although not statistically significantly so, of a monophyletic relationship between W. scintillans and T. pacificus.     

鞘翅目昆虫线粒体基因组研究进展

鞘翅目（Coleoptera）是世界上最具多样性的类群,具有很高的生态和形态多样性,这些多样性吸引了很多进化生物学家和分类学家的关注。随着分子生物学的发展,分子生物学技术广泛应用于鞘翅目系统学的研究,但随着研究的深入,简单的分子片段已经不能满足研究的需求,需要发掘更新的分子标记。近年来,线粒体全基因组已经成为鞘翅目分子系统学研究中很重要的分子标记之一,并广泛地应用于鞘翅目昆虫各个阶元的研究中。本文就鞘翅目线粒体全基因组的概况、研究进展及存在问题进行了总结和讨论。目前,鞘翅目线粒体基因组的研究主要包括物种线粒体基因组组成与结构、分子系统学和分子进化等方面。线粒体基因组在解决系统发育和进化方面表现出了很多的优越性,然而也存在着一些缺点,如序列难获得、基因类型单一、各基因进化速率不同、应用较局限等。     

The complete chloroplast and mitochondrial DNA sequence of Ostreococcus tauri: organelle genomes of the smallest eukaryote are examples of compaction

The complete nucleotide sequence of the mt (mitochondrial) and cp (chloroplast) genomes of the unicellular green alga Ostreococcus tauri has been determined. The mt genome assembles as a circle of 44,237 bp and contains 65 genes. With an overall average length of only 42 bp for the intergenic regions, this is the most gene-dense mt genome of all Chlorophyta. Furthermore, it is characterized by a unique segmental duplication, encompassing 22 genes and covering 44% of the genome. Such a duplication has not been observed before in green algae, although it is also present in the mt genomes of higher plants. The quadripartite cp genome forms a circle of 71,666 bp, containing 86 genes divided over a larger and a smaller single-copy region, separated by 2 inverted repeat sequences. Based on genome size and number of genes, the Ostreococcus cp genome is the smallest known among the green algae. Phylogenetic analyses based on a concatenated alignment of cp, mt, and nuclear genes confirm the position of O. tauri within the Prasinophyceae, an early branch of the Chlorophyta.     

蜱螨线粒体基因组研究进展

蜱螨亚纲包括蜱类和螨类, 是节肢动物中物种多样性最高的类群之一。本文综述了当前已测序的28种蜱螨线粒体基因组的研究成果。概括起来, 蜱螨线粒体基因组具有以下特点： （1）大小变异显著, 其中柑橘全爪螨Panonychus citri线粒体基因组在目前已测节肢动物中最小（13 077 bp）; （2）一般碱基组成偏向A和T, 但6种蜱螨具有相反的GC-偏斜（正值）; （3）基因组的碱基组成及A+T富集区的位置、 长度和拷贝数等变异显著, 其中4种叶螨的A+T含量最高, 其A+T富集区在目前已测节肢动物中最短（44~57 bp）; （4）基因高度重排, 特别是真螨总目的种类, 但重排与高分类阶元无相关性; （5）真螨总目部分螨类的tRNA基因极度缩短, 不能形成经典的三叶草二级结构。作者建议要进一步测定更多蜱螨的线粒体基因组, 验证蜱螨非典型tRNA基因的生物学功能性, 分析蜱螨线粒体基因组的分子进化机制, 开展蜱螨线粒体转录组研究等。     

Sequencing and phylogenetic analysis of the Pyrgilauda ruficollis(Aves,Passeridae) complete mitochondrial genome

In this study,both long PCR and conserved primers walking sequencing methods were used to determine the complete sequence of the of Pyrgilauda ruficollis mitochondrial genome(KC836121).The results showed that the complete mitochondrial genome of P.ruficollis is 16909 bp in length with 55.0%A+T content,harboring the typical 37 genes.The mitogenome had the same gene order with that of Podoces hendersoni.All protein coding genes started with ATG codon,except ND3 with GTG.For the stop codon usage,most genes terminate with codons TAA or TAG,but ND5 terminated with AGA,while ND1 and COI genes with AGG,and both the genes COIII and ND4 have an incomplete termination codon(T).The secondary structures of 22 tRNA genes were also predicted,showing that all tRNAs can form typical clover-leaf secondary structures,except for the tRNASer(AGN)which loses the DHU arm,while tRNAPhe harbor an extra nucleotide inserted in the TψC arm.The predicted secondary structures of 12S rRNA and16S rRNA exhibit 47 helices in 4 domains and 60 helices in 6 domains respectively.The control region of P.ruficollis with the length of 1 305 bp was located between tRNAGlu and tRNAPhe,and typical domains of which could be found as other bird groups.Using the data from 13 mitochondrial protein-coding genes,results of a final phylogenetic analysis strongly supports the traditional view that P.ruficollis is closely related with Passeridae and Fringillidae.