Molecular mechanisms of extensive mitochondrial gene rearrangement in plethodontid salamanders

Extensive gene rearrangement is reported in the mitochondrial genomes of lungless salamanders (Plethodontidae). In each genome with a novel gene order, there is evidence that the rearrangement was mediated by duplication of part of the mitochondrial genome, including the presence of both pseudogenes and additional, presumably functional, copies of duplicated genes. All rearrangement-mediating duplications include either the origin of light-strand replication and the nearby tRNA genes or the regions flanking the origin of heavy-strand replication. The latter regions comprise nad6, trnE, cob, trnT, an intergenic spacer between trnT and trnP and, in some genomes, trnP, the control region, trnF, rrnS, trnV, rrnL, trnL1, and nad1. In some cases, two copies of duplicated genes, presumptive regulatory regions, and/or sequences with no assignable function have been retained in the genome following the initial duplication; in other genomes, only one of the duplicated copies has been retained. Both tandem and nontandem duplications are present in these genomes, suggesting different duplication mechanisms. In some of these mitochondrial DNAs, up to 25% of the total length is composed of tandem duplications of noncoding sequence that includes putative regulatory regions and/or pseudogenes of tRNAs and protein-coding genes along with the otherwise unassignable sequences. These data indicate that imprecise initiation and termination of replication, slipped-strand mispairing, and intramolecular recombination may all have played a role in generating repeats during the evolutionary history of plethodontid mitochondrial genomes.     

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.     

啮总目昆虫的线粒体基因组多样性及系统发育研究进展

啮总目包括啮虫目（皮虱和书虱）和虱目（羽虱和吸虱）,是农业和医学等领域具有重要经济意义和研究价值的类群,目前已鉴定和描述的物种超过10 000个。啮总目昆虫线粒体基因组的变异性在昆虫各类群中最为剧烈,这些变异包括基因组的结构、基因排序、基因含量和链上分布等诸多方面。本文全面分析和总结了啮总目昆虫裂化线粒体基因组的进化属性,并结合两侧对称动物线粒体基因组的裂化特征重构了线粒体基因组环裂化的过程。引入“线粒体基因组核型”的概念来描述动物线粒体基因组丰富的变异程度。动物线粒体的染色体有减小的趋势,而线粒体基因组的裂化正是体现这种趋势的一种重要策略。同时,总结和探讨了目前具有争议的啮总目主要类群间的系统发育关系。本综述为啮总目昆虫线粒体基因组学、啮总目系统发生关系以及两侧对称动物线粒体基因组进化模式的研究提供一个新的视角。     

Bird mitochondrial gene order: insight from 3 warbler mitochondrial genomes

Two main gene orders exist in birds: the ancestral gene order and the remnant control region (CR) 2 gene order. These gene orders differ by the presence of 1 or 2 copies of the CR, respectively. Among songbirds, Oscines were thought to follow the ancestral gene order, with the exception of the lyrebird and Phylloscopus warblers. Here, we determined the complete mitochondrial genome sequence of 3 non-Phylloscopus warblers species and found that the blackcap (Sylvia atricapilla) and the reed warbler (Acrocephalus scirpaceus) have 2 almost identical copies of the CR, whereas the eastern orphean warbler (Sylvia crassirostris) follows the remnant CR 2 gene order. Our results contradict previous studies suggesting that Acrocephalus and most sylvioid warblers exhibit the ancestral gene order. We were able to trace this contradiction to a misidentification of gene order from polymerase chain reaction length determination. We thus suggest that passerine gene order evolution needs to be revised.     

The mitochondrial genome of the lizard Calotes versicolor and a novel gene inversion in South Asian draconine agamids

A complete mitochondrial DNA (mtDNA) sequence was determinedfor the lizard Calotes versicolor (Reptilia; Agamidae). The16,670-bp genome with notable shorter genes for some protein-codingand tRNA genes had the same gene content as that found in othervertebrates. However, a novel gene arrangement was found inwhich the proline tRNA (trnP) gene is located in the light strandinstead of its typical heavy-strand position, providing thefirst known example of gene inversion in vertebrate mtDNAs.A segment of mtDNA encompassing the trnP gene and its flankinggenes and the control region was amplified and sequenced forvarious agamid taxa to investigate timing and mechanism of thegene inversion. The inverted trnP gene organization was sharedby all South Asian draconine agamids examined but by none ofthe other Asian and African agamids. Phylogenetic analyses includingclock-free Bayesian analyses for divergence time estimationsuggested a single occurrence of the gene inversion on a lineageleading to the draconine agamids during the Paleogene period.This gene inversion could not be explained by the tandem duplication/randomloss model for mitochondrial gene rearrangements. Our availablesequence data did not provide evidence for remolding of thetrnP gene by an anticodon switch in a duplicated tRNA gene.Based on results of sequence comparisons and other circumstantialevidence, we hypothesize that inversion of the trnP gene wasoriginally mediated by a homologous DNA recombination and thatthe de novo gene organization that does not disrupt expressionof mitochondrial genes has been maintained in draconine mtDNAsfor such a long period of time.     

The age of the Arabidopsis thaliana genome duplication

We estimate the timing of the Arabidopsis thaliana whole-genome duplication by means of phylogenetic and statistical analysis, and propose two possible scenarios for the duplication. The first one, based on the assumption that the duplicated segments diverged from an autotetraploid form, places the duplication at about 38 million years ago, after the Arabidopsislineage diverged from that of soybean (Glycine max) and before it diverged from its sister genus, Brassica. The second scenario assumes that the ancestor was allotetraploid, and suggests that the duplication is younger than 38 million years and may have contributed to the Arabidopsis-Brassica divergence. In each case, our estimate places the age of the genome duplication as significantly younger than previously reported.     

土蜂科线粒体基因组序列测定和分析

【目的】本研究旨在通过针尾部(Aculeata)昆虫线粒体基因组系统发育分析认知土蜂科(Scoliidae)的单系性及系统发育位置。【方法】利用Illumina Hiseq2500二代测序技术测序土蜂科3属5种的线粒体基因组,并进行注释和分析;基于针尾部昆虫36个线粒体基因组13个蛋白质编码基因(protein-coding genes, PCGs)和2个rRNA基因序列采用最大似然法(maximum likelihood, ML)和贝叶斯法(Bayesian inference, BI)法构建系统发育树。【结果】新测序的土蜂科5个线粒体基因组为五带波壁土蜂Colpa quinquecincta线粒体基因组(GenBank登录号：OM103696),齿石波壁土蜂Colpa tartara线粒体基因组(GenBank登录号：OM103697),厚大长腹土蜂Megacampsomeris grossa线粒体基因组(GenBank登录号：OM103796),台湾大长腹土蜂Megacampsomeris formosensis线粒体基因组(GenBank登录号：OM142776)和斯式土蜂Sc...     

A chloroplast derived trnH gene is expressed in the mitochondrial genome of gramineous plants

We reported previously that the mitochondrial sequence that contains the chloroplast-derived trnH gene has been highly conserved in the region around one terminus of the junction between chloroplast-derived and mitochondrion-specific sequences in most of the gramineous plants analyzed [15]. The results of RT-PCR, northern hybridization, in vitro capping and ribonuclease protection experiments show that the chloroplast-derived trnH gene is transcribed from a putative promoter that is located in the mitochondrion-specific sequence. Gene expression in this region seems to be correlated with the conservation of the sequence at the junction between the chloroplast-derived fragment and the mitochondrion-specific sequence.     

Phylogeny, recombination, and mechanisms of stepwise mitochondrial genome reorganization in mantellid frogs from Madagascar

In Malagasy frogs of the family Mantellidae, the genus Mantellais known to possess highly reorganized mitochondrial (mt) genomeswith the following characteristics: 1) some rearranged genepositions, 2) 2 distinct genes and a pseudogene correspondingto the transfer RNA gene for methionine (trnM), and 3) 2 controlregions (CRs) with almost identical nucleotide sequences. Theseunique genomic features were observed concentrated between theduplicated CRs surrounding cytochrome b (cob) and nicotinamideadenine dinucleotide dehydrogenase subunit 2 (cnad2) genes.To elucidate the mechanisms and evolutionary pathway that yieldedthe derived genome condition, we surveyed the reorganized genomicportion for all 12 mantellid genera. Our results show that themt genomes of 7 genera retain the ancestral condition. In contrast,adding to Mantella, 4 genera of the subfamily Mantellinae, Blommersia,Guibemantis, Wakea, and Spinomantis, share several derived genomiccharacters. Furthermore, mt genomes of these mantellines showedadditional structural divergences, resulting in different genomeconditions between them. The high frequency of genomic reorganizationdoes not correlate with nucleotide substitution rate. The encounteredmt genomic conditions also suggest the occurrences of stepwisegene duplication and deletion events during the evolution ofmantellines. Simultaneously, the majority of duplication eventsseems to be mediated by general (homologous) or illegitimaterecombination, and general recombination also plays a role inconcerted sequence evolution between multiple CRs. Consideringour observations and recent conditional evidences, the followingoutlines can be expected for recombination processes in mt genomereorganization. 1) The CR is the "hot spot" of recombination;2) highly frequent recombination between CRs may be mediatedby a replication fork barrier lying in the CR; 3) general recombinationhas a potential to cause gene rearrangement in upstream regionsof multiple CRs as the results of gene conversion and unequalcrossing over processes. Our results also suggest that recombinationactivity is not a direct cause of convergent gene rearrangement;rather, homoplasious gene rearrangement seems to be mediatedby persistence of a copied genomic condition through severallineage splits and subsequent parallel deletions.     

Gene loss and evolutionary rates following whole-genome duplication in teleost fishes

Teleost fishes provide the first unambiguous support for ancient whole-genome duplication in an animal lineage. Studies in yeast or plants have shown that the effects of such duplications can be mediated by a complex pattern of gene retention and changes in evolutionary pressure. To explore such patterns in fishes, we have determined by phylogenetic analysis the evolutionary origin of 675 Tetraodon duplicated genes assigned to chromosomes, using additional data from other species of actinopterygian fishes. The subset of genes, which was retained in double after the genome duplication, is enriched in development, signaling, behavior, and regulation functional categories. The evolutionary rate of duplicate fish genes appears to be determined by 3 forces: 1) fish proteins evolve faster than mammalian orthologs; 2) the genes kept in double after genome duplication represent the subset under strongest purifying selection; and 3) following duplication, there is an asymmetric acceleration of evolutionary rate in one of the paralogs. These results show that similar mechanisms are at work in fishes as in yeast or plants and provide a framework for future investigation of the consequences of duplication in fishes and other animals.     

The mitochondrial genome of the moss Physcomitrella patens sheds new light on mitochondrial evolution in land plants

The phylogenetic positions of bryophytes and charophytes, together with their genome features, are important for understanding early land plant evolution. Here we report the complete nucleotide sequence (105,340 bp) of the circular-mapping mitochondrial DNA of the moss Physcomitrella patens. Available evidence suggests that the multipartite structure of the mitochondrial genome in flowering plants does not occur in Physcomitrella. It contains genes for 3 rRNAs (rnl, rns, and rrn5), 24 tRNAs, and 42 conserved mitochondrial proteins (14 ribosomal proteins, 4 ccm proteins, 9 nicotinamide adenine dinucleotide dehydrogenase subunits, 5 ATPase subunits, 2 succinate dehydrogenase subunits, apocytochrome b, 3 cytochrome oxidase subunits, and 4 other proteins). We estimate that 5 tRNA genes are missing that might be encoded by the nuclear genome. The overall mitochondrial genome structure is similar in Physcomitrella, Chara vulgaris, Chaetosphaeridium globosum, and Marchantia polymorpha, with easily identifiable inversions and translocations. Significant synteny with angiosperm and chlorophyte mitochondrial genomes was not detected. Phylogenetic analysis of 18 conserved proteins suggests that the moss-liverwort clade is sister to angiosperms, which is consistent with a previous analysis of chloroplast genes but is not consistent with some analyses using mitochondrial sequences. In Physcomitrella, 27 introns are present within 16 genes. Nine of its intron positions are shared with angiosperms and 4 with Marchantia, which in turn shares only one intron position with angiosperms. The phylogenetic analysis as well as the syntenic structure suggest that the mitochondrial genomes of Physcomitrella and Marchantia retain prototype features among land plant mitochondrial genomes.     

The temporal distribution of gene duplication events in a set of highly conserved human gene families

Using a data set of protein translations associated with map positions in the human genome, we identified 1520 mapped highly conserved gene families. By comparing sharing of families between genomic windows, we identified 92 potentially duplicated blocks in the human genome containing 422 duplicated members of these families. Using branching order in the phylogenetic trees, we timed gene duplication events in these families relative to the primate-rodent divergence, the amniote-amphibian divergence, and the deuterostome-protostome divergence. The results showed similar patterns of gene duplication times within duplicated blocks and outside duplicated blocks. Both within and outside duplicated blocks, numerous duplications were timed prior to the deuterostome-protostome divergence, whereas others occurred after the amniote-amphibian divergence. Thus, neither gene duplication in general nor duplication of genomic blocks could be attributed entirely to polyploidization early in vertebrate history. The strongest signal in the data was a tendency for intrachromosomal duplications to be more recent than interchromosomal duplications, consistent with a model whereby tandem duplication-whether of single genes or of genomic blocks-may be followed by eventual separation of duplicates due to chromosomal rearrangements. The rate of separation of tandemly duplicated gene pairs onto separated chromosomes in the human lineage was estimated at 1.7 x 10(-9) per gene-pair per year.     

The evolution of mitochondrial genomes in modern frogs (Neobatrachia): nonadaptive evolution of mitochondrial genome reorganization

Background

Although mitochondrial (mt) gene order is highly conserved among vertebrates, widespread gene rearrangements occur in anurans, especially in neobatrachians. Protein coding genes in the mitogenome experience adaptive or purifying selection, yet the role that selection plays on genomic reorganization remains unclear. We sequence the mitogenomes of three species of Glandirana and hot spots of gene rearrangements of 20 frog species to investigate the diversity of mitogenomic reorganization in the Neobatrachia. By combing these data with other mitogenomes in GenBank, we evaluate if selective pressures or functional constraints act on mitogenomic reorganization in the Neobatrachia. We also look for correlations between tRNA positions and codon usage.

Results

Gene organization in Glandirana was typical of neobatrachian mitogenomes except for the presence of pseudogene trnS (AGY). Surveyed ranids largely exhibited gene arrangements typical of neobatrachian mtDNA although some gene rearrangements occurred. The correlation between codon usage and tRNA positions in neobatrachians was weak, and did not increase after identifying recurrent rearrangements as revealed by basal neobatrachians. Codon usage and tRNA positions were not significantly correlated when considering tRNA gene duplications or losses. Change in number of tRNA gene copies, which was driven by genomic reorganization, did not influence codon usage bias. Nucleotide substitution rates and d_N/d_S ratios were higher in neobatrachian mitogenomes than in archaeobatrachians, but the rates of mitogenomic reorganization and mt nucleotide diversity were not significantly correlated.

Conclusions

No evidence suggests that adaptive selection drove the reorganization of neobatrachian mitogenomes. In contrast, protein-coding genes that function in metabolism showed evidence for purifying selection, and some functional constraints appear to act on the organization of rRNA and tRNA genes. As important nonadaptive forces, genetic drift and mutation pressure may drive the fixation and evolution of mitogenomic reorganizations.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-691) contains supplementary material, which is available to authorized users.     

Whole genome duplication of intra- and inter-chromosomes in the tomato genome

Whole genome duplication(WGD)events have been proven to occur in the evolutionary history of most angiosperms.Tomato is considered a model species of the Solanaceae family.In this study,we describe the details of the evolutionary process of the tomato genome by detecting collinearity blocks and dating the WGD events on the tree of life by combining two different methods:synonymous substitution rates(Ks)and phylogenetic trees.In total,593 collinearity blocks were discovered out of 12 pseudo-chromosomes constructed. It was evident that chromosome 2 had experienced an intra-chromosomal duplication event.Major inter-chromosomal duplication occurred among all the pseudo-chromosome.We calculated the Ks value of these collinearity blocks.Two peaks of Ks distribution were found,corresponding to two WGD events occurring approximately 36-82 million years ago(MYA)and 148-205 MYA.Additionally, the results of phylogenetic trees suggested that the more recent WGD event may have occurred after the divergence of the rosidasterid clade,but before the major diversification in Solanaceae.The older WGD event was shown to have occurred before the divergence of the rosid-asterid clade and after the divergence of rice-Arabidopsis(monocot-dicot).     

Complete mtDNA sequence of the North American freshwater mussel,Lampsilis ornata (Unionidae): an examination of the evolution and phylogenetic utility of mitochondrial genome organization in Bivalvia (Mollusca)

Molluscs in general, and bivalves in particular, exhibit an extraordinary degree of mitochondrial gene order variation when compared with other metazoans. Two factors inhibiting our understanding the evolution of gene rearrangement in bivalves are inadequate taxonomic sampling and failure to examine gene order in a phylogenetic framework. Here, we report the first complete nucleotide sequence (16,060 bp) of the mitochondrial (mt) genome of a North American freshwater bivalve, Lampsilis ornata (Mollusca: Paleoheterodonta: Unionidae). Gene order and mt genome content is examined in a comparative phylogenetic framework for Lampsilis and five other bivalves, representing five families. Mitochondrial genome content is shown to vary by gene duplication and loss among taxa and between male and female mitotypes within a species. Although mt gene arrangement is highly variable among bivalves, when optimized on an independently derived phylogenetic hypothesis, it allows for the reconstruction of ancestral gene order states and indicates the potential phylogenetic utility of the data. However, the interpretation of reconstructed ancestral gene order states must take in to account both the accuracy of the phylogenetic estimation and the probability of character state change across the topology, such as the presence/absence of atp8 in bivalve lineages. We discuss what role, if any, doubly uniparental inheritance (DUI) and recombination between sexual mitotypes may play in influencing gene rearrangement of the mt genome in some bivalve lineages.     

昆虫线粒体基因组重排的研究进展

动物线粒体基因组通常组成稳定,基因排列也相对保守,极少发生重组。但是昆虫的线粒体基因组具有重排的可能性,而且这些重排事件可能为系统发育研究提供重要的信息。因此,深入研究昆虫线粒体基因组的重排可能有助于解决具有争议的系统发生关系。本文对昆虫线粒体基因组的重排类型、重排机理和重排在昆虫系统发育分析中的应用等方面的研究进展进行了介绍。