斐豹蛱蝶线粒体基因组全序列的测定和分析(英文)

该研究对斐豹蛱蝶(Argyreus hyperbius)(鳞翅目:蛱蝶科)线粒体基因组全序列进行了测定和初步分析。结果表明:斐豹蛱蝶线粒体基因全序列全长为15156bp,包含13个蛋白质编码基因、22个tRNA和2个rRNA基因以及1个非编码的A+T富集区,基因排列顺序与其它鳞翅目种类一致;线粒体全序列核苷酸组成和密码子使用显示出明显的A+T偏好(80.8%)和轻微的AT偏移(AT skew,?0.019)。基因组中共存在11个2～52bp不等的基因间隔区,总长96bp;以及14个1～8bp不等的基因重叠区,总长34bp。除COI以CGA作为起始密码子外,13个蛋白质编码基因中的其余12个基因是以ATN作为起始密码子。除COI和COII基因是以单独的一个T为终止密码子,其余11个蛋白质编码基因都是以TAA结尾的。除了缺少DHU臂的tRNASer(AGN),其余的tRNA基因都显示典型的三叶草结构。tRNA(AGN)和ND1之间的基因间隔区包含一个ATACTAA结构域,这个结构域在鳞翅目中是保守的。A+T富集区没有较大的多拷贝重复序列,但是包含一些微小重复结构:ATAGA结构域下游的20bp poly-T结构,ATTTA结构域后的(AT)9重复,以及位于tRNAMet上游的5bp poly-A结构等。这项研究所揭示的斐豹蛱蝶的线粒体基因组特征,不仅为认识蛱蝶科的遗传多样性贡献数据,而且对于该物种的保护生物学、群体遗传学、谱系地理及演化研究等具有重要意义。     

THE COMPLETE MITOCHONDRIAL GENOME OF AQUARIUS PALUDUM (FABRICIUS) (INSECTA, HEMIPTERA,GERRIDAE)

昆虫纲半翅目异翅亚目黾蝽科圆臀大黾蝽Aquarius paludum(Fabricius,1794)已成为生物学研究的理想生物材料之一,为更全面了解其分子生物学特征,本研究测定了圆臀大黾蝽Aquarius paludum线粒体基因组全序列.该基因组全长15380 bP,为双链环状DNA分子,包含13个蛋白编码基因、22个tRNA基因、2个rRNA基因及一个控制区.其基因排序与已报道的其它大部分异翅亚目类群排列方式相同.该基因组基因排列紧密,共观察到64 bp基因间隔(除控制区781 bp外)与33 bp基因重叠.全基因组AT含量为75.7％,而控制区AT含量仅为66.2％,密码子使用也显示出AT使用偏好.13个蛋白编码基因中,除COⅠ、ND5使用TTG作为起始密码子外,其余使用ATV.此外,7个蛋白编码基因使用常规三联终止密码子TAA,TAG作为终止密码子,其余以T作为终止密码子,下游为同链编码的tRNA基因.在tRNA-Ser (GGT)二级结构中,DHU臂缺失,未形成典型的三叶草结构.     

一种石磺科贝类线粒体基因组全序列分析

石磺线粒体基因组全序列对研究石磺科分子系统进化具有重要意义。利用LA-PCR技术对一种石磺Platevin-dexmortoni线粒体基因组全序列进行了测定和分析。结果表明,线粒体基因组序列全长13 991 bp,碱基组成分别为27.27%A、16.78%C、20.23%G、35.72%T;由22个tRNA、2个rRNA、13个蛋白编码基因和25个长度为2-118 bp的非编码区组成。4个蛋白质编码基因和5个tRNA基因从L链编码,其余基因均从H链编码。蛋白质基因的起始密码子,除ND2为GTG以外,均为典型的起始密码子ATN。ND2和Cytb基因使用了不完全终止密码子T,其余基因均使用典型的TAA或TAG。预测了22个tRNA基因的二级结构,发现tRNASer和TrnaAsn缺少DHU臂,tRNASer和tRNAThr的反密码子环上有9个碱基,而不是通常的7个碱基。最长的非编码区含有两个类似于的tRNAGln和tRNAPhy的二级结构。     

黄毛纺蚋线粒体基因组全序列测定与分析

利用PCR步移法对黄毛纺蚋的线粒体基因组全序列进行了测定和分析。黄毛纺蚋线粒体基因组全长15904 bp(Gen Bank序列号KP793690),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939 bp的非编码区。A、T、C、G碱基含量分别为39.1%、35.8%、10.4%、14.7%。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双翅目昆虫相同。13个蛋白编码基因中除COI以TTG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COI和ND4L以单独的T作为终止密码子。在所测得的22个tRNA基因中,除tRNASer(AGN)缺少DHU臂外,其余tRNA均能形成典型的三叶草结构。     

大壁虎线粒体基因组全序列及其结构(英文)

采用长PCR扩增、克隆和引物步行等方法,测定了大壁虎(Gekkogecko)线粒体基因组全序列。序列全长16435bp,共有13个蛋白质编码基因、2个rRNA基因和22个tRNA基因。基因组的组成、顺序、编码链的选择、tRNA的结构、较低的碱基G含量、对碱基T的偏好以及GC和AT偏斜,都与大部分脊椎动物相同或相近。但有些特征揭示了壁虎类的原始性蛋白质编码基因密码子第3位表现为对碱基A的偏好,更接近两栖类和鱼类而不是羊膜动物;标准终止密码子(TAA)只出现于3个蛋白质编码基因中,比大部分脊椎动物少。tRNA基因核苷酸长度为63～76nt,除了tRNACys和tRNASer(AGY)缺少D臂,其余的二级结构均呈典型的三叶草状。     

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。     

圆臀大黾蝽(昆虫纲,半翅目,黾蝽科)线粒体全基因组注释(英文)

昆虫纲半翅目异翅亚目黾蝽科圆臀大黾蝽 Aquarius paludum ( Fabricius,1794) 已成为生物学研究的理想生物材料之一,为更全面了解其分子生物学特征,本研究测定了圆臀大黾蝽 Aquarius paludum线粒体基因组全序列。该基因组全长15 380 bp,为双链环状 D N A 分子,包含 13 个蛋白编码基因、22 个 tRNA 基因、2 个 rRNA 基因及一个控制区。其基因排序与已报道的其它大部分异翅亚目类群排列方式相同。该基因组基因排列紧密,共观察到 64 bp 基因间隔 ( 除控制区 781 bp 外) 与 33 bp 基因重叠。全基因组 AT 含量为75. 7 % ,而控制区 AT 含量仅为 66. 2 % ,密码子使用也显示出 AT 使用偏好。13 个蛋白编码基因中,除 COⅠ、ND5 使用 TTG 作为起始密码子外,其余使用 ATV。此外,7 个蛋白编码基因使用常规三联终止密码子 TAA,TAG 作为终止密码子,其余以 T 作为终止密码子,下游为同链编码的tRN A 基因。在 tRN A-Ser ( G C T ) 二级结构中,D HU 臂缺失,未形成典型的三叶草结构。     

小长蝽线粒体基因组全序列测定与长蝽总科系统发育分析

为了解小长蝽Nysius ericae(Schilling)线粒体基因组结构及长蝽总科的分子系统发育关系。本试验采用Illumina MiSeq测序平台对小长蝽线粒体基因进行测序,对基因组序列进行拼装、注释和特征分析,利用最大似然法和贝叶斯法构建基于12种长蝽总科昆虫线粒体全基因组核苷酸序列的系统发育树。小长蝽线粒体基因组全长为16 330 bp(GenBank登录号：MW465654),基因组包括13个蛋白编码基因(PCGs),22个tRNA基因,2个rRNA基因和1段非编码控制区。11个蛋白质编码基因的起始密码子为典型的ATN;cox1,nad4l的起始密码子为TTG。cob的终止密码子为TAG,其余蛋白编码基因的终止密码子为TAA。只有trnS1缺少DHU臂,其余tRNA基因均能形成典型的三叶草结构。12种长蝽总科昆虫线粒体全基因组序列构建的昆虫系统发育树结果显示,小长蝽与Nysius plebeius具有更近的亲缘关系,且与传统形态学分类基本一致。小长蝽线粒体基因组符合长蝽总科线粒体基因组的一般特征。结果表明小长蝽与N.plebeius的亲缘关系更近。     

猫蛱蝶线粒体基因组全序列分析

采用PCR步移法对猫蛱蝶Timelaea maculata线粒体基因组全序列进行了测定和分析.分析结果表明:猫蛱蝶线粒体基因组全长15 178 bp,包括13个蛋白编码基因、22个tRNA基因、2个rRNA基因和一段长度为382 bp的A+T富含区,基因排列顺序与其它已知鳞翅目昆虫相同.猫蛱蝶线粒体基因组中存在很高的A+T含量(81.1％).13个蛋白编码基因中除CO Ⅰ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.COⅡ和ND4基因使用了不完全终止密码子T,其余基因均以典型的TAA、TAG为终止密码子.在所测得的22个tRNA基因中,除tRNAser(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,猫蛱蝶的A+T富含区中有一段由“ATAGAA”引导的保守的多聚T结构,长度为19 bp,并散在着一些长短不一的串联重复单元.     

ANALYSIS OF COMPLETE MITOCHONDRIAL GENOME OF SASAKIA CHARONDA COREANA (LEPIDOPTERA, NYMPHALIDA)

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15 233 bp,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tRNASer (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.     

A complete mitochondrial genome sequence of Ogura-type male-sterile cytoplasm and its comparative analysis with that of normal cytoplasm in radish (Raphanus sativus L.)

ABSTRACT: BACKGROUND: Plant mitochondrial genome has unique features such as large size, frequent recombination and incorporation of foreign DNA. Cytoplasmic male sterility (CMS) is caused by rearrangement of the mitochondrial genome, and a novel chimeric open reading frame (ORF) created by shuffling of endogenous sequences is often responsible for CMS. The Ogura-type male-sterile cytoplasm is one of the most extensively studied cytoplasms in Brassicaceae. Although the gene orf138 has been isolated as a determinant of Ogura-type CMS, no homologous sequence to orf138 has been found in public databases. Therefore, how orf138 sequence was created is a mystery. In this study, we determined the complete nucleotide sequence of two radish mitochondrial genomes, namely, Ogura- and normal-type genomes, and analyzed them to reveal the origin of the gene orf138. RESULTS: Ogura- and normal-type mitochondrial genomes were assembled to 258,426-bp and 244,036-bp circular sequences, respectively. Normal-type mitochondrial genome contained 33 protein-coding and three rRNA genes, which are well conserved with the reported mitochondrial genome of rapeseed. Ogura-type genomes contained same genes and additional atp9. As for tRNA, normal-type contained 17 tRNAs, while Ogura type contained 17 tRNAs and one additional trnfM. The gene orf138 was specific to Ogura-type mitochondrial genome, and no sequence homologous to it was found in normal-type genome. Comparative analysis of the two genomes revealed that radish mitochondrial genome consists of 11 syntenic regions (length >3kb, similarity >99.9%). It was shown that short repeats and overlapped repeats present in the edge of syntenic regions were involved in recombination events during evolution to interconvert two types of mitochondrial genome. Ogura-type mitochondrial genome has four unique regions (2,803 bp, 1,601 bp, 451 bp and 15,255 bp in size) that are non-syntenic to normal-type genome, and the gene orf138 was found to be located at the edge of the largest unique region. Blast analysis performed to assign the unique regions showed that about 80% of the region was covered by short homologous sequences to the mitochondrial sequences of normal-type radish or other reported Brassicaceae species, although no homology was found for the remaining 20% of sequences. CONCLUSIONS: Ogura-type mitochondrial genome was highly rearranged compared with the normal-type genome by recombination through one large repeat and multiple short repeats. The rearrangement has produced four unique regions in Ogura-type mitochondrial genome, and most of the unique regions are composed of known Brassicaceae mitochondrial sequences. This suggests that the regions unique to the Ogura-type genome were generated by integration and shuffling of pre-existing mitochondrial sequences during the evolution of Brassicaceae, and novel genes such as orf138 could have been created by the shuffling process of mitochondrial genome.     

The mitochondrial genome structure of the clouded leopard (Neofelis nebulosa).

The complete 16 844 bp mitochondrial genome of Neofelis nebulosa has been sequenced and compared with the complete mitochondrial genomes of Felis catus and the Acinonyx jubatus. The base composition of the mitochondrial genome of N. nebulosa is as follows: A, 5343 bp (31.7%); C, 4441 bp (26.4%); G, 2491 bp (14.8%); T, 4569 bp (27.1%). The genome complement and the gene order of this mitochondrial genome was found to be typical of those reported for other mammals. Several unusual features of this genome, however, were found. First, in protein-coding regions, AT bias in the genome was not prevalent in the third position of codons, as it is in most other mammals, but was found in the second position of codons. Second, in tRNA regions, tRNASer (AGY), which lacked the "DHU" arm, could not be folded into the typical cloverleaf-shaped structure. Third, in the control region, no repetitive sequences (RS)-2 were found. However, RS-2 repetitive motifs usually occurr in the control regions of most great cats. In addition, 4 variable sites were found in CSB-3 of the control region. Fourth, AT content in the control region of the mtDNA from the clouded leopard was lower than it is in other regions.     

Species‐specific mitochondrial gene rearrangements in biting midges and vector species identification

Abstract Partial mitochondrial gene sequences of 16 Culicoides species were determined to elucidate phylogenetic relations among species and to develop a molecular identification method for important virus vector species. In addition, the analysis found mitochondrial gene rearrangement in several species. Sequences of the mitochondrial genome region, cox1–trnL2–cox2 (1940–3785 bp) of 16 Culicoides and additional sequences were determined in some species, including whole mitochondrial genome sequences of Culicoides arakawae. Nine species showed common organization in this region, with three genes cox1–trnL2–cox2 and a small or no intergenic region (0–30 bp) between them. The other seven species showed translocation of tRNA and protein‐coding genes and/or insertion of AT‐rich non‐coding sequences (65–1846 bp) between the genes. The varied gene rearrangements among species within a genus is very rare for mitochondrial genome organization. Phylogenetic analyses based on the sequences of cox1+cox2 suggest a few clades among Japanese Culicoides species. No relationships between phylogenetic closeness and mitochondrial gene rearrangements were observed. Sequence data were used to establish a polymerase chain reaction tool to distinguish three important vector species from other Culicoides species, for which classification during larval stages is not advanced and identification is difficult.     

Mitochondrial genomics of gadine fishes: implications for taxonomy and biogeographic origins from whole-genome data sets.

Phylogenetic analysis of 13 substantially complete mitochondrial DNA genome sequences (14,036 bp) from 10 taxa of gadine codfishes and pollock provides highly corroborated resolution of outstanding questions on their biogeographic evolution. Of 6 resolvable nodes among species, 4 were supported by >95% of bootstrap replications in parsimony, distance, likelihood, and similarly high posterior probabilities in bayesian analyses, one by 85%-95% according to the method of analysis, and one by 99% by one method and a majority of the other two. The endemic Pacific species, walleye pollock (Theragra chalcogramma), is more closely related to the endemic Atlantic species, Atlantic cod (Gadus macrocephalus), than either is to a second Pacific endemic, Pacific cod (Gadus macrocephalus). The walleye pollock should thus be referred to the genus Gadus as originally described (Gadus chalcogrammus Pallas 1811). Arcto-Atlantic Greenland cod, previously regarded as a distinct species (G. ogac), are a genomically distinguishable subspecies within pan-Pacific G. macrocephalus. Of the 2 endemic Arctic Ocean genera, Polar cod (Boreogadus) as the outgroup to Arctic cod (Arctogadus) and Gadus sensu lato is more strongly supported than a pairing of Boreogadus and Arctogadus as sister taxa. Taking into consideration historical patterns of hydrogeography, we outline a hypothesis of the origin of the 2 endemic Pacific species as independent but simultaneous invasions through the Bering Strait from an Arcto-Atlantic ancestral lineage. In contrast to the genome data, the complete proteome sequence (3830 amino acids) resolved only 3 nodes with >95% confidence, and placed Alaska pollock outside the Gadus clade owing to reversal mutations in the ND5 locus that restore ancestral, non-Gadus, amino acid residues in that species.     

中国蒙古马与国外纯血马mtDNA D-Loop高变区序列比较

比较分析了4匹中国蒙古马和4匹国外纯血马的线立体DNA（mtDNA）D-Loop高变区400bp核苷酸序列的变异情况。结果发现,4匹中国蒙古马mtDNA D-Loop高变区的平均核苷酸变异率为3.69%,而纯血马的为4.00%,其核苷酸变异类型均包括转换、颠换和缺失3种形式,其中以转换最为常见。核苷酸变异基因座多,并且存在长度变异,不同变异在个体之间差异也很大,因此说明中国蒙古马和国外纯血马的mtDNA D-Loop高变区都具有丰富的多态性。Abstract：Mitochondrial DNA D-Loop varied region 400bp sequence variations in 4 Chinese Mongolian horses and 4 External Thoroughbred horses were analyzed in this experiment. The results showed that the average nucleotide mutational rate of mtDNA D-Loop varied region in 4 Chinese Mongolian horses was 3.69%,while External Thoroughbred horses were 4.00%. Three types of mutations including transition,transversion and deletion were all found in the investigated mtDNA D-Loop regions,of which transition was the most frequent. Nucleotide mutational loci were abundant,length mutations were found and great differences were all observed among the 8 horses. It showed there existed much polymorphism in the mitochondrial DNA D-Loop varied region of Chinese Mongolian horses and External Thoroughbred horses.     

双翅目昆虫线粒体基因组结构特点及其测序通用引物的设计和应用

研究双翅目昆虫线粒体基因组的结构特点, 并设计其测序的通用引物, 为今后双翅目昆虫线粒体基因组的研究提供参考和依据。利用比较基因组学和生物信息学方法, 分析了已经完全测序的26个双翅目昆虫线粒体基因组的结构特点、 碱基组成和保守区, 并据此设计了双翅目昆虫基因组测序的通用引物。结果表明： 双翅目昆虫线粒体基因组长14 503~19 517 bp, 其结构保守, 含有37个编码基因, 包括13个蛋白质编码基因, 22个tRNA编码基因和2个rRNA编码基因, 此外还包含一段长度差异很大的非编码区(AT富含区)。基因组内基因排列次序稳定, 除个别基因外, 其余都与黑腹果蝇Drosophila melanogaster基因排列次序一致。基因组的碱基组成不均衡, AT含量在72.59%~85.15%之间, 碱基使用存在偏向性, 偏好使用AC碱基。全基因组的核苷酸和氨基酸序列保守, 共鉴定了11个保守区。在保守区内共设计了26对双翅目线粒体基因组测序通用引物, 扩增的目标片段都在1 200 bp以内。将该套通用引物用于葱蝇Delia antiqua线粒体全基因组测序, 结果证明其高效、 合用。     

滇金丝猴线粒体D-loop 片段SNPs 位点的鉴别及初步分析

本文利用已测序的157 个滇金丝猴控制区(D-loop)片段,通过与参考序列比对,鉴别了线粒体D-loop 片段中的52 个SNP (Single Nucleotide Polymorphisms)位点,定义了30 种滇金丝猴单倍型,排除概率为0. 938。谱系及种群遗传结构分析结果与以前利用D-loop 片段的研究结果相似。同时表明基于粪便样品进行保护遗传学、谱系生物地理学、种群遗传学等研究时,与线粒体标记和微卫星标记相比,SNP 标记可能具有一定的优越性,并建议进一步分析滇金丝猴线粒体D-loop 全序列甚至线粒体全基因组上的SNPs 位点的信息,以促进滇金丝猴保护遗传学等研究的开展。     

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。     

入侵害虫甘薯凹胫跳甲的鉴定及线粒体基因组分析

【目的】基于形态学鉴定和分子生物学技术确认甘薯凹胫跳甲Chaetocnema confinis是否入侵中国大陆,测定甘薯凹胫跳甲线粒体基因组序列,分析基因组结构及其系统发育关系。【方法】应用显微镜观察从广东不同地点采集的甘薯凹胫跳甲成虫的形态特征,并扩增cox1基因DNA序列进行分子鉴定;利用Illumina MiSeq测序平台对甘薯凹胫跳甲线粒体基因组进行测序、拼装、注释和特征分析;基于亲缘关系相近种属的线粒体基因组序列进行共线性分析和构建系统发育树,分析基因重排和系统发育关系。【结果】形态和分子鉴定结果表明大陆甘薯上发现的跳甲为甘薯凹胫跳甲。甘薯凹胫跳甲线粒体基因组序列大小为15 685 bp,包括有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;这37个基因之间排列紧凑,间隔总长度101 bp,排列顺序与模式昆虫Drosophila yakuba线粒体基因排列顺序相同。甘薯凹胫跳甲线粒体基因组A+T含量为77.3%,具有明显的AT偏向性。13个蛋白质编码基因的起始密码子均为ATN。在22个tRNA基因中除trnS1的DHU臂缺失,trnD, trnG, trnN和trnT的二级结构中缺少TψC环外,其余17个都能形成典型的三叶草式二级结构,另trnK的反密码子突变为UUU,trnS1的反密码子突变为UCU。甘薯凹胫跳甲的控制区片段长度仅有60 bp,是目前已报道的昆虫线粒体基因组中最短的控制区。基于线粒体基因组的系统发育分析表明,甘薯凹胫跳甲与跳甲亚科(Alticinae)黄曲条跳甲Phyllotreta striolata亲缘关系最近。【结论】甘薯凹胫跳甲已经入侵到中国大陆。本研究获得了甘薯凹胫跳甲的线粒体基因组序列,为防控甘薯凹胫跳甲和分析叶甲科(Chrysomelidae)各种属间的系统发育关系奠定了基础。