蒙古狼线粒体基因组序列分析及其系统发育地位

应用Long-PCR和克隆测序法得到蒙古狼(Canis lupus chanco)线粒体基因组全序列,结合GenBank中现有犬科动物线粒体基因组数据,应用最大简约法(MP)、最大似然法(ML)和Bayesian分析法对蒙古狼的系统发育地位进行了探讨。结果如下:蒙古狼线粒体基因组全长16709bp,包含13个蛋白质编码基因、22个tRNA基因、2个rRNA基因和1个非编码区。序列碱基的组成存在明显的A-T偏好性。tRNA基因中除tRNA-Ser(AGY)缺少双氢尿嘧啶(DHU)臂以外,其余均能折叠成典型的三叶草二级结构。大多数蛋白质编码基因的起始和终止密码子与犬科动物有报道相同,COXⅡ基因的起始密码子为ATA,与其他犬科动物不同。基于12S rRNA+16S rRNA+H链上的12个蛋白质编码基因的联合数据的系统发育分析发现,在已报道的狼亚种数据中,西藏狼(Canis lupus laniger)的分化时间最早,其次为阿拉伯狼(Canis lupus arabs),蒙古狼与欧亚狼(Canis lupuslupus)的系统发育地位最为接近。     

犬科动物线粒体基因组特征分析

在基因组水平上,分析了已知犬科动物线粒体基因组的特征。结果表明：其基因排列顺序相同;具有AT含量高,G含量最低的碱基偏好性;存在基N间隔和基N重叠;CUA（Leu）,Auu（Ile）,AUA（Met）等密码子使用率最高,密码子第3位G使用率最低;轻链复制起点序列组成和二级结构高度保守;在犬、狼、郊狼控制区存在10bp的相似重复序列,赤狐序列差异较大。     

红角辉蝽和紫翅果蝽线粒体完整基因组测序及蝽亚科系统发育分析(半翅目: 蝽科)(英文)

【目的】本研究对红角辉蝽Carbula crassiventris和紫翅果蝽Carpocoris purpureipennis完整线粒体基因组测序,以探究蝽亚科(Pentatominae)线粒体基因组特征并重建其系统发育关系。【方法】使用Illumina MiSeq测序平台测定红角辉蝽和紫翅果蝽线粒体基因组全序列,并进行组装和注释。基于这2个种和其他30个蝽亚科分类单元线粒体基因组的13个蛋白质编码基因的第1和2位密码子以及2个rRNA基因的核苷酸序列,利用贝叶斯和最大似然法重建蝽亚科系统发育树。【结果】红角辉蝽和紫翅果蝽的线粒体基因组全长分别为15 824 和16 575 bp, 包含13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个控制区。蝽亚科内线粒体基因组基因排列顺序保守且没有发现基因重排。此外,蝽亚科内的碱基组成、密码子使用和RNA结构均较为保守; 控制区重复序列拥有不同的长度、类型和拷贝数。基于贝叶斯法和最大似然法重建的系统发育树显示二星蝽族(Eysarcorini)、果蝽族(Carpocorini)、稻绿蝽族(Nezarini)和Antestiini构成一个稳定分枝。【结论】系统发育分析支持辉蝽属Carbula应属于二星蝽族,而果蝽属Carpocoris、斑须蝽属Dolycoris和珠蝽属Rubiconia同属于果蝽族。     

黄侧异腹胡蜂线粒体基因组全序列测定和分析

【目的】测序和分析黄侧异腹胡蜂Parapolybia crocea线粒体基因组,并在线粒体基因组水平探讨异腹胡蜂属Parapolybia在胡蜂科中的系统发育地位。【方法】用Illumina二代测序技术测定黄侧异腹胡蜂线粒体基因组全序列,分析其结构特点和碱基组成;使用最大似然法(maximum likelihood,ML)构建胡蜂科7个种线粒体基因组的系统发育树,分析其在胡蜂科中的系统发育关系。【结果】黄侧异腹胡蜂线粒体基因组全长16 619 bp(Gen Bank登录号:KY679828),包含13个蛋白质编码基因,22个t RNA基因,2个r RNA基因(rrn S和rrn L)和1个控制区,基因排列顺序与推测的昆虫祖先序列不完全一致;全部蛋白质编码基因的起始密码子均为ATN,终止密码子除CYTB和ND1为TAG外,其余均为TAA;除t RNASer(AGN)的DHU臂缺失外,其他t RNA均能折叠成典型的三叶草结构;控制区中存在一个18 bp的T-stretch结构和2段串联重复序列。胡蜂科7个种基于线粒体基因组的系统发育关系表现为蜾蠃亚科+(胡蜂亚科+马蜂亚科),异腹胡蜂属与马蜂属Polistes同属于马蜂亚科。【结论】黄侧异腹胡蜂线粒体基因组存在基因重排现象。基于线粒体基因组的胡蜂科系统发育关系与传统的形态分类学结果一致:异腹胡蜂属隶属于马蜂亚科,马蜂亚科与胡蜂亚科的亲缘关系较其与蜾蠃亚科更近。     

枣食芽象甲线粒体基因组全序列测定与系统发育分析

【目的】从线粒体基因组水平上探讨枣食芽象甲Scythropus yasumatsui与近缘种的系统发育关系。【方法】利用Illumina MiSeq测序平台对枣食芽象甲线粒体基因组进行测序,对基因组序列进行拼装、注释和特征分析;利用贝叶斯法和最大似然法构建基于象甲科13个物种的线粒体基因组13个蛋白质编码基因核苷酸序列的系统发育树。【结果】结果表明,枣食芽象甲线粒体基因组全长为16 472 bp (GenBank登录号: MF807224),包含13个蛋白质编码基因、22个tRNA基因、2个rRNA基因和2个非编码控制区,37个基因的排列顺序与祖先昆虫的线粒体基因排列顺序一致。13个蛋白质编码基因的起始密码子为ATN,其中除了cob和nad1基因的完全终止密码子为TAG外,其余11个基因的完全终止密码子为TA(A)。22个tRNA基因中除了trnS1缺少DHU臂,反密码子由GCT变为TCT外,其余均能形成典型的三叶草结构。基于13个蛋白质编码基因序列构建的系统发育树结果显示,象甲科8个亚科系统发育关系为：(((隐喙象亚科(Cryptorhynchinae)+(象虫亚科(Curculioninae)+魔喙象亚科(Molytinae)))+长小蠹亚科(Platypodinae))+(粗喙象亚科(Entiminae)+Cyclominae亚科))+隐颏象亚科(Dryophthorinae)+小蠹亚科(Scolytinae))。【结论】在13种象甲科昆虫物种中,同属于粗喙象亚科的枣食芽象甲与南美果树象甲Naupactus xanthographus在系统发育树中聚为同一分支,表明基于线粒体基因组全序列的分子系统发育结果与传统的形态分类结果是一致的。     

玉米蚜线粒体基因组测序及蚜族系统发育分析

为探究玉米蚜(Rhopalosiphum maidis)线粒体基因组结构特征及蚜族(Aphidini)的系统发育关系,本研究利用高通量测序技术测定了玉米蚜线粒体基因组全序列。选择已知的蚜族18个物种线粒体基因组作为内群,选择长管蚜族(Macrosiphini)2个物种线粒体基因组作为外群,利用最大似然法(maximum likelihood method)和贝叶斯法(Bayesian inference method)重建蚜族的系统发育关系。玉米蚜的线粒体基因组全长为15 096 bp,呈环状,包括13个蛋白质编码基因(protein-coding genes)、 22个tRNA基因和2个rRNA基因,还有一段非编码控制区。13个蛋白质编码基因的起始密码子全为ATN; 3个蛋白质编码基因cox1、nad4和nad5具有不完整的终止密码子T或TA,其余10个蛋白质编码基因为完整的终止密码子TAA或TAG。本研究利用线粒体基因组数据重建了蚜族的系统发育关系,最大似然法和贝叶斯法构建的蚜族的系统发育关系是基本一致的。其中,色蚜属(Melanaphis)、桃粉蚜属(Hyalopterus)、蚜...     

异刺草螽线粒体基因组序列分析

本研究采用高通量测序技术对异刺草螽的基因组进行测序,并组装得到了完整的线粒体基因组序列。结果显示:异刺草螽线粒体基因组序列全长16 038 bp,包含13个蛋白质编码基因、22个t RNA基因、2个r RNA基因和1个控制区。异刺草螽线粒体基因组的总碱基组成如下:A为37.3%、C为15.4%、G为10.3%、T为36.9%,A+T含量较高,为74.2%。异刺草螽线粒体基因的排列与祖先序列相同,该线粒体基因组序列为直翅目螽斯科的系统发生和进化研究提供了重要的分子基础。     

麻竖毛天牛线粒体基因组测定及天牛科线粒体基因组比较分析

【目的】线粒体基因组分析是研究昆虫系统发育的重要手段。本研究通过测定麻竖毛天牛Thyestilla gebleri(Faldermann,1835)线粒体基因组,比较分析天牛科Cerambycidae线粒体基因组的特征,进而初步探讨麻竖毛天牛系统发育地位和天牛科部分类群之间的系统进化关系。【方法】采用引物步移法测定麻竖毛天牛线粒体基因组全序列。参照Gen Bank收录的16种天牛线粒体基因组序列进行基因注释;采用在线软件t RNAscan-SE Search Server对转运RNA(t RNA)的二级结构进行了预测。通过对16种天牛的线粒体基因组进行重新注释,结合本研究获得的麻竖毛天牛线粒体基因组进行序列特征比较分析。基于11个蛋白编码基因的核苷酸序列,利用最大似然法构建了天牛科17种天牛的系统发育树。【结果】麻竖毛天牛线粒体基因组全长15 505 bp,A+T含量为74.07%,包含13个蛋白编码基因(PCGs),2个核糖体RNA(r RNA)基因,22个t RNA基因和一个长度为872 bp的控制区,未发现基因重排。通过比对17种天牛的线粒体基因组,发现长翅暗天牛Vesperus conicicollis一个t RNA(trn P)基因的移位。17种天牛的t RNA中,trn S1(AGN)的D臂均缺失,其余t RNA都具有典型的三叶草结构。大部分种类的蛋白编码基因起始密码子为典型的ATN(ATA、ATT、ATC、ATG),只有部分种类的Nad1、COI、ATP8基因存在特殊的起始密码子(TTG、AAC、AAT、GTG),终止密码子均为常见的TAR(TAA、TAG)或不完全的T和TA。系统发育树中,6个亚科分别单独分支,其中,麻竖毛天牛与云斑白条天牛Batocera lineolata聚为一支。【结论】麻竖毛天牛线粒体基因组符合天牛线粒体基因组的一般特征;除少数t RNA基因存在重排外,天牛科线粒体基因排列相对稳定;基于线粒体基因组的系统发育分析支持天牛科6个亚科的单系性,麻竖毛天牛和云斑白条天牛亲缘关系较近。     

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。     

社鼠（Niviventer confucianus）线粒体基因组全序列分析

社鼠（Niviventer confucianus）属于啮齿目（Rodentia）、鼠科（Muridae）、白腹鼠属（Niviventer）,关于该物种的分子系统学研究极少。为获取社鼠线粒体基因组全序列,提取其基因组总DNA,参照近缘物种线粒体基因组全序列设计34对特异性引物,利用PCR扩增全部片段后进行测序,之后对其基因组组成及结构特点进行了初步分析。结果表明,社鼠线粒体基因组全序列长16 281 bp（GenBank收录号：KJ152220）,包含22个tRNA基因、13个蛋白质编码基因、2个rRNA基因和1个非编码控制区;基因组核苷酸组成为34.0%A、28.6%T、24.9%C、12.5%G。将所得序列与社鼠近缘物种（川西白腹鼠、小家鼠、褐家鼠）的线粒体全基因组进行比较,结果显示,四个物种的线粒体基因组虽然在基因组大小、部分tRNA二级结构、部分蛋白质编码基因的起始或终止密码子及控制区长度和碱基组成上有差异,但基因组结构和序列特征方面都具有较高的相似性。四个物种线粒体全基因组间的遗传距离显示,社鼠与川西白腹鼠距离最近,而与小家鼠距离最远。该研究为利用线粒体全基因组信息进行啮齿类分子系统学研究提供了有价值的资料。     

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.     

The complete mitochondrial genome and phylogenetic analysis of Nyctereutes procyonoides

The complete mitochondrial genome sequence of the raccoon dog (Nyctereutes procyonoides) was determined by using the long and accurate polymerase chain reaction. The entire mitochondrial genome sequence is 16,713 bp in length contains two ribosomal RNA genes, 13 protein-coding genes, 22 transfer RNA genes and 1 control region. Most mitochondrial genes are encoded on the H strand, except for the ND6 gene and 8 tRNA genes. The base compositions of mitochondrial genomes present clearly A–T skew. All the transfer RNA genes can be folded into the typical cloverleaf-shaped structure except tRNA-Ser (AGY), which lacks the dihydrouridine arm. Protein-coding genes mainly initiate with ATG and terminate with TAA. Some reading frame intervals and overlaps are found in the mitochondrial genome. The control region can be divided into three domains: the extended termination associated sequences (ETASs) domain, the central conserved domain and the conserved sequence blocks (CSBs) domain. Three conserved sequence blocks (CSBs) and one extended termination associated sequences (ETAS-1) is found in the control region. The phylogenetic analysis based on the concatenated data set of 14 genes in the mitochondrial genome of Canidae shows that the raccoon dog has close phylogenetic position with the red fox (Vulpes vulpes) and they constitute a clade which has an equil evolutionary position with the clade formed by the genera Canis and Cuon.     

犬科的线粒体细胞色素b DNA序列及其分子系统学研究

通过对犬科的赤狐、蓝狐、貉和狼４种的线粒体细胞色素ｂ约３７２ｂｐＤＮＡ片段序列分析,结合ＧｅｎＢａｎｋ中狗、西门豺和非洲野犬３种的该区段ＤＮＡ序列的比较,共发现１１３个核苷酸位点存在变异（约３０％）。ＮＪ法构建的分子系统树显示,非洲野犬最先从犬科动物中分化出来;犬属的我狼、狗和西门豺等３种为系统树上独立的一支,且其分歧的时间较赤狐、蓝狐和貉早;赤狐和蓝狐具有较近的亲缘关系。上述结果与形态的观点基本     

Use of RAPD technique in evolution studies of four species in the family Canidae

The RAPD-PCR technique was applied to identify genetic markers able to distinguish between four canid species: the arctic fox (Alopex lagopus), red fox (Vulpes vulpes), Chinese raccoon dog (Nyctereutes procyonoides procyonoides) and six breeds of the domestic dog (Canis familiaris). A total of 29 ten-nucleotide arbitrary primers were screened for their potential use in the differentiation of these species. Ten primers amplified RAPD profiles that made it possible to distinguish between the investigated taxa. A number of species-specific bands was scored within RAPD profiles produced by these primers: 35.6% of all the polymorphic bands were unique to the Chinese raccoon dog, 29.6% were unique to the domestic dog, 21.2% were diagnostic for the red fox and 13.6% for the arctic fox. No breed-specific fragments were amplified from canine DNA; however, three primers produced bands characteristic for the dog, but not present in all of the investigated breeds. A Neighbor-Joining tree constructed on the basis of the analysis of RAPD profiles amplified by six primers revealed that the phylogenetic distance between the dog and the arctic fox is larger than the distance between the dog and the red fox. The phylogenetic branch of the Chinese raccoon dog was the most distinct on the dendrogram, suggesting that this species belongs to a different phylogenetic lineage. Obtained results make it possible to conclude that RAPD analysis can be a powerful tool for developing molecular markers useful in distinguishing between species of the family Canidae and for studying their phylogenetic relations.     

Association of MC3R gene polymorphisms with body weight in the red fox and comparative gene organization in four canids

There are five genes encoding melanocortin receptors. Among canids, the genes have mainly been studied in the dog (MC1R, MC2R and MC4R). The MC4R gene has also been analysed in the red fox. In this report, we present a study of chromosome localization, comparative sequence analysis and polymorphism of the MC3R gene in the dog, red fox, arctic fox and Chinese raccoon dog. The gene was localized by FISH to the following chromosome: 24q24‐25 in the dog, 14p16 in the red fox, 18q13 in the arctic fox and NPP4p15 in the Chinese raccoon dog. A high identity level of the MC3R gene sequences was observed among the species, ranging from 96.0% (red fox – Chinese raccoon dog) to 99.5% (red fox – arctic fox). Altogether, eight polymorphic sites were found in the red fox, six in the Chinese raccoon dog and two in the dog, while the arctic fox appeared to be monomorphic. In addition, association of several polymorphisms with body weight was analysed in red foxes (the number of genotyped animals ranged from 319 to 379). Two polymorphisms in the red fox, i.e. a silent substitution c.957A>C and c.*185C>T in the 3′‐flanking sequence, showed a significant association (P < 0.01) with body weight.     

Widespread occurrence of a domestic dog mitochondrial DNA haplotype in southeastern US coyotes

Sequence analysis of the mitochondrial DNA control region from 112 southeastern US coyotes (Canis latrans) revealed 12 individuals with a haplotype closely related to those in domestic dogs. Phylogenetic analyses grouped this new haplotype in the dog/grey wolf (Canis familiaris/Canis lupus) clade with 98% bootstrap support. These results demonstrate that a male coyote hybridized with a female dog, and female hybrid offspring successfully integrated into the coyote population. The widespread distribution of this haplotype from Florida to West Virginia suggests that the hybridization event occurred long ago before the southeastern USA was colonized by coyotes. However, it could have occurred in the southeastern USA before the main front of coyotes arrived in the area between male coyotes released for sport and a local domestic dog. The introgression of domestic dog genes into the southeastern coyote population does not appear to have substantially affected the coyote's genetic, morphological, or behavioural integrity. However, our results suggest that, contrary to previous reports, hybridization can occur between domestic and wild canids, even when the latter is relatively abundant. Therefore, hybridization may be a greater threat to the persistence of wild canid populations than previously thought.     

A noninvasive method for distinguishing among canid species: amplification and enzyme restriction of DNA from dung

Endangered San Joaquin kit foxes Vulpes macrotis mutica can be sympatrically distributed with as many as four other canids: red fox, gray fox, coyote and domestic dog. Canid scats are often found during routine fieldwork, but cannot be reliably identified to species. To detect and study the endangered kit fox, we developed mitochondrial DNA markers that can be amplified from small amounts of DNA extracted from scats. We amplified a 412-bp fragment of the mitochondrial cytochrome- b gene from scat samples and digested it with three restriction enzymes. The resulting restriction profiles discriminated among all five canid species and correctly identified 10 'unknown' fox scats to species in blind tests. We have applied our technique to identify canids species for an environmental management study and a conservation study. We envision that our protocol, and similar ones developed for other endangered species will be greatly used for conservation management in the future.     

Chromosomal evolution of the Canidae. II. Divergence from the primitive carnivore karyotype

The Giemsa-banding patterns of chromosomes from the arctic fox (Alopex lagopus), the red fox (Vulpes vulpes), the kit fox (Vulpes macrotis), and the raccoon dog (Nyctereutes procyonoides) are compared. Despite their traditional placement in different genera, the arctic fox and the kit fox have an identical chromosome morphology and G-banding pattern. The red fox has extensive chromosome arm homoeology with these two species, but has only two entire chromosomes in common. All three species share some chromosomes with the raccoon dog, as does the high diploid-numbered grey wolf (Canis lupus, 2n = 78). Moreover, some chromosomes of the raccoon dog show partial or complete homoeology with metacentric feline chromosomes which suggests that these are primitive canid chromosomes. We present the history of chromosomal rearrangements within the Canidae family based on the assumption that a metacentric-dominated karyotype is primitive for the group.     

Y‐chromosome evidence supports widespread signatures of three‐species Canis hybridization in eastern North America

There has been considerable discussion on the origin of the red wolf and eastern wolf and their evolution independent of the gray wolf. We analyzed mitochondrial DNA (mtDNA) and a Y‐chromosome intron sequence in combination with Y‐chromosome microsatellites from wolves and coyotes within the range of extensive wolf–coyote hybridization, that is, eastern North America. The detection of divergent Y‐chromosome haplotypes in the historic range of the eastern wolf is concordant with earlier mtDNA findings, and the absence of these haplotypes in western coyotes supports the existence of the North American evolved eastern wolf (Canis lycaon). Having haplotypes observed exclusively in eastern North America as a result of insufficient sampling in the historic range of the coyote or that these lineages subsequently went extinct in western geographies is unlikely given that eastern‐specific mtDNA and Y‐chromosome haplotypes represent lineages divergent from those observed in extant western coyotes. By combining Y‐chromosome and mtDNA distributional patterns, we identified hybrid genomes of eastern wolf, coyote, gray wolf, and potentially dog origin in Canis populations of central and eastern North America. The natural contemporary eastern Canis populations represent an important example of widespread introgression resulting in hybrid genomes across the original C. lycaon range that appears to be facilitated by the eastern wolf acting as a conduit for hybridization. Applying conventional taxonomic nomenclature and species‐based conservation initiatives, particularly in human‐modified landscapes, may be counterproductive to the effective management of these hybrids and fails to consider their evolutionary potential.     

A comparative analysis of MC4R gene sequence, polymorphism, and chromosomal localization in Chinese raccoon dog and Arctic fox

Numerous mutations of the human melanocortin receptor type 4 (MC4R) gene are responsible for monogenic obesity, and some of them appear to be associated with predisposition or resistance to polygenic obesity. Thus, this gene is considered a functional candidate for fat tissue accumulation and body weight in domestic mammals. The aim of the study was comparative analysis of chromosome localization, nucleotide sequence, and polymorphism of the MC4R gene in two farmed species of the Canidae family, namely the Chinese raccoon dog (Nycterutes procyonoides procyonoides) and the arctic fox (Alopex lagopus). The whole coding sequence, including fragments of 3'UTR and 5'UTR, shows 89% similarity between the arctic fox (1276 bp) and Chinese raccoon dog (1213 bp). Altogether, 30 farmed Chinese raccoon dogs and 30 farmed arctic foxes were searched for polymorphisms. In the Chinese raccoon dog, only one silent substitution in the coding sequence was identified; whereas in the arctic fox, four InDels and two single-nucleotide polymorphisms (SNPs) in the 5'UTR and six silent SNPs in the exon were found. The studied gene was mapped by FISH to the Chinese raccoon dog chromosome 9 (NPP9q1.2) and arctic fox chromosome 24 (ALA24q1.2-1.3). The obtained results are discussed in terms of genome evolution of species belonging to the family Canidae and their potential use in animal breeding.