Mitogenomes provide new insights into the evolutionary history of Prodiamesinae (Diptera: Chironomidae)

Evolutionary analysis of Prodiamesinae has long been impeded by lack of information, and its phylogenetic relationship with Orthocladiinae remains questionable. Here, ten complete mitochondrial genomes (mitogenomes) of Orthocladiinae sensu lato were newly sequenced, including three Prodiamesinae species and seven Orthocladiinae species. Coupled with published mitogenomes, a total of 12 mitogenomes of Orthocladiinae sensu lato were selected for a comparative mitogenomic analysis and phylogenetic reconstruction. Mitogenomes of Orthocladiinae sensu lato are conserved in structure, and all genes arrange the same gene order as the ancestral insect mitogenome. Nucleotide composition is highly biased, and the control region displayed the highest A + T content. All protein-coding genes are under purifying selection, and the ATP8 evolves at the fastest rate. In addition, the mitogenomes of Orthocladiinae sensu lato are highly conserved, and they are practically useful for phylogenetic inference, suggesting a re-classification of Orthocladiinae by sinking Prodiamesinae as a subgroup of Orthocladiinae.     

The phylogenetic position of toadfishes (order Batrachoidiformes) in the higher ray-finned fish as inferred from partitioned Bayesian analysis of 102 whole mitochondrial genome sequences

In a previous study based on 100 whole mitochondrial genome (mitogenome) sequences, we sought to provide a new perspective on the ordinal relationships of higher ray-finned fish (Actinopterygii). The study left unexplored the phylogenetic position of toadfishes (order Batrachoidiformes), as data were unavailable owing to technical difficulties. In the present study, we successfully determined mitogenomic sequences for two toadfish species ( Batrachomoeus trispinosus and Porichthys myriaster ) and found that the difficulties resulted from unusual gene arrangements and associated repetitive non-coding sequences. Unambiguously aligned, concatenated mitogenomic sequences (13 461 bp) from 102 higher actinopterygians (excluding the ND6 gene and control region) were divided into five partitions (1st, 2nd and 3rd codon positions of the protein-coding genes, tRNA genes and rRNA genes) and partitioned Bayesian analyses were conducted. The resultant phylogenies strongly suggest that the toadfishes are not members of relatively primitive higher actinopterygians (Paracanthopterygii), but belong to a crown group of actinopterygians (Percomorpha), as was demonstrated for ophidiiform eels (Ophidiiformes) and anglerfishes (Lophiiformes) in the previous study. We propose revised limits of major unranked categories for higher actinopterygians and a new name (Berycomorpha) for a clade comprising two reciprocally paraphyletic orders (Beryciformes and Stephanoberyciformes) based on the present mitogenomic phylogenies.  © 2005 The Linnean Society of London, Biological Journal of the Linnean Society , 2005, 85 , 289–306.     

Characterisation of the complete mitochondrial genome of the black-footed abalone Haliotis iris

The complete mitogenome of Haliotis iris, an economically important shellfish endemic to New Zealand, was sequenced for the first time. The mitogenome was 17,131?base pairs (bp) in length and contained 13 protein-coding genes (PCGs), 2 ribosomal RNA (rRNA) genes, 22 transfer RNA (tRNA) genes and a control region. All 13 genes were initiated by the start codon ATG, except for nad5 (ATA). Two typical stop codons, TAA and TAG, were present. All of the tRNAs could be folded into typical cloverleaf secondary structures except tRNA^Ser1 and tRNA^Lys, which lacked a DHU stem and complete amino acid acceptor stem, respectively. The control region was 1132?bp in length and contained six AT tandem repeats. According to the gene order of the mitogenome, the 30 analysed Vetigastropoda species could be classified into three types—type I: over half of the studied species were very similar to the gastropod ancestral gene order, and the rearrangements occurred in five tRNAs; type II: eight species were found to be missing several tRNA genes; type III: Fissurellidae, Lepetodrilidae showed a large inverted fragment.     

Comparative mitochondrial and chloroplast genomics of a genetically distinct form of Sargassum contributing to recent “Golden Tides” in the Western Atlantic

Over the past 5 years, massive accumulations of holopelagic species of the brown macroalga Sargassum in coastal areas of the Caribbean have created “golden tides” that threaten local biodiversity and trigger economic losses associated with beach deterioration and impact on fisheries and tourism. In 2015, the first report identifying the cause of these extreme events implicated a rare form of the holopelagic species Sargassum natans (form VIII). However, since the first mention of S. natans VIII in the 1930s, based solely on morphological characters, no molecular data have confirmed this identification. We generated full‐length mitogenomes and partial chloroplast genomes of all representative holopelagic Sargassum species, S. fluitans III and S. natans I alongside the putatively rare S. natans VIII, to demonstrate small but consistent differences between S. natans I and VIII (7 bp differences out of the 34,727). Our comparative analyses also revealed that both S. natans I and S. natans VIII share a very close phylogenetic relationship with S. fluitans III (94‐ and 96‐bp differences of 34,727). We designed novel primers that amplified regions of the cox2 and cox3 marker genes with consistent polymorphic sites that enabled differentiation between the two S. natans forms (I and VIII) from each other and both from S. fluitans III in over 150 Sargassum samples including those from the 2014 golden tide event. Despite remarkable gene synteny and sequence conservation, the three Sargassum forms differ in morphology, ecology, and distribution patterns, warranting more extensive interrogation of holopelagic Sargassum genomes as a whole.     

Phylogenetic relationships and divergence dates of softshell turtles (Testudines: Trionychidae) inferred from complete mitochondrial genomes

The softshell turtles (Trionychidae) are one of the most widely distributed reptile groups in the world, and fossils have been found on all continents except Antarctica. The phylogenetic relationships among members of this group have been previously studied; however, disagreements regarding its taxonomy, its phylogeography and divergence times are still poorly understood as well. Here, we present a comprehensive mitogenomic study of softshell turtles. We sequenced the complete mitochondrial genomes of 10 softshell turtles, in addition to the GenBank sequence of Dogania subplana, Lissemys punctata, Trionyx triunguis, which cover all extant genera within Trionychidae except for Cyclanorbis and Cycloderma. These data were combined with other mitogenomes of turtles for phylogenetic analyses. Divergence time calibration and ancestral reconstruction were calculated using BEAST and RASP software, respectively. Our phylogenetic analyses indicate that Trionychidae is the sister taxon of Carettochelyidae, and support the monophyly of Trionychinae and Cyclanorbinae, which is consistent with morphological data and molecular analysis. Our phylogenetic analyses have established a sister taxon relationship between the Asian Rafetus and the Asian Palea + Pelodiscus + Dogania + Nilssonia + Amyda, whereas a previous study grouped the Asian Rafetus with the American Apalone. The results of divergence time estimates and area ancestral reconstruction show that extant Trionychidae originated in Asia at around 108 million years ago (MA), and radiations mainly occurred during two warm periods, namely Late Cretaceous–Early Eocene and Oligocene. By combining the estimated divergence time and the reconstructed ancestral area of softshell turtles, we determined that the dispersal of softshell turtles out of Asia may have taken three routes. Furthermore, the times of dispersal seem to be in agreement with the time of the India–Asia collision and opening of the Bering Strait, which provide evidence for the accuracy of our estimation of divergence time. Overall, the mitogenomes of this group were used to explore the origin and dispersal route of Trionychidae and have provided new insights on the evolution of this group.     

访花昆虫野蚜蝇线粒体基因组结构分析

野蚜蝇Syrphus torvus(Osten-Sacken)成虫具访花习性,是重要的传粉昆虫;幼虫捕食蚜虫,是蚜虫重要天敌之一.本研究通过高通量测序、组装拼接获得了完整的野蚜蝇线粒体基因组全序列(GenBank登录号:MW074962),其序列全长为16 444 bp,包含13个蛋白编码基因(PCGs)、22个tRNAs、2个rRNAs和D-loop区.野蚜蝇线粒体全序列A+T含量为80.6％,G+C含量为19.4％,表现出明显的A+T偏斜.除了 COXI、ATP8、ATP6和ND1的起始密码子为TTG,其它9个PCGs以ATN为起始密码子;COXI的终止密码子为不完整的T--,ATP6为TAG,其余11个PCGs的终止子为TAA.22个tRNAs的二级结构均为典型的三叶草结构,并预测了野蚜蝇rRNAs的二级结构.野蚜蝇D-loop区存在重复序列和茎环结构,22种蚜蝇科基因间隔区与重叠区具有6个保守区域.基于24个物种(22个蚜蝇科和2个缟蝇科)的PCGs序列,通过贝叶斯法(BI)和最大似然法(ML)构建系统发育树,结果显示,野蚜蝇和黑足蚜蝇Syrphus vitripennis互为姊妹种,支持了蚜蝇亚科Syrphinae的单系性,两种拓扑结构中管蚜蝇亚科Eristalinae均没有聚为一支.该研究结果丰富了蚜蝇科线粒体基因组学基本数据,为进一步深化蚜蝇科系统发育关系讨论提供了参考.     

The enigmatic Crimean green lizard (Lacerta viridis magnifica) is extinct but not valid: Mitogenomics of a 120-year-old museum specimen reveals historical introduction

It has been proposed that Lacerta viridis magnifica Sobolevssky, 1930 represents an extinct species or subspecies of green lizard endemic to the southern Crimea. Using NGS protocols optimized for heavily degraded DNA, we sequenced the complete mitogenome of one of the originally formalin-preserved specimens collected in the late 19th century. A comparison with sequence data of other green lizards revealed that L. v. magnifica is a junior synonym of the northern subspecies of the western green lizard (L. b. bilineata Daudin, 1802), which occurs at least 1,500 km away, beyond the distribution ranges of other green lizards. In medieval times, a Genoese colony existed in the Crimean region where the extinct green lizards occurred. Until the early 20th century, close ties to Italy persisted, and locals of Genoese descent sent their children for education to Italy, where L. b. bilineata occurs. This suggests that the extinct Crimean green lizards have been introduced accidentally or intentionally from Italy. Our study exemplifies the value of historical formalin-preserved museum specimens for clarifying the status of questionable rare or extinct taxa.     

重伞灵芝线粒体基因组在灵芝种间鉴定中的应用

线粒体是“动力工厂”,能够进行氧化代谢实现能量的转化,参与三羧酸循环形成ATP。随着分子生物学和生物信息学技术的发展,担子菌灵芝属中已有几种灵芝的线粒体基因组被相继报道,但尚未有对重伞灵芝线粒体基因组的报道。本研究通过对重伞灵芝YX线粒体基因组进行组装注释,比较分析了与其他灵芝属物种的差异,根据差异序列构建分子标记对重伞灵芝菌株快速鉴定。结果显示重伞灵芝线粒体基因组大小为67 340bp的闭合环形结构,含有15个普通蛋白编码基因,28个tRNA基因,以及rRNA的大小亚基基因。共5个基因含有12个内含子,主要为IB型,部分为ID型,包含LAGLIDADG_1 superfamily、GIY-YIG_Cterm superfamily保守结构域。根据重伞灵芝线粒体cox2基因设计的特异性引物扩增结果显示：4株重伞灵芝的cox2基因片段均可准确扩增,且扩增不出其他灵芝物种的cox2基因片段。基于各灵芝菌株线粒体cox2基因序列构建系统进化树,可以将4株重伞灵芝归在同一分支上,并且同源性为98%,与ITS鉴定结果一致。可见,基于线粒体基因cox2特异性引物可以快速地对重伞灵芝进行鉴定,且只需通过观察扩增条带的有无,无需测序,省时省力。