Project description:Although the majority of metazoan mitochondrial genomes (mtDNAs) contain the same 37 genes, including 22 encoding transfer RNAs (tRNAs), the recognition of orthologs is not always straightforward. Here we demonstrate that inferring tRNA orthologs among taxa by using anticodon triplets and deduced secondary structure can be misleading: through a process of tRNA duplication and mutation in the anticodon triplet, remolded leucine (LUUR) tRNA genes have repeatedly taken over the role of isoaccepting LCUN leucine tRNAs within metazoan mtDNA. In the present work, data from within the gastropods and a broad survey of metazoan mtDNA suggest that tRNA leucine duplication and remolding events have occurred independently at least seven times within three major animal lineages. In all cases where the mechanism of gene remolding can be inferred with confidence, the direction is the same: from LUUR to LCUN. Gene remolding and its apparent asymmetry have significant implications for the use of mitochondrial tRNA gene orders as phylogenetic markers. Remolding complicates the identification of orthologs and can result in convergence in gene order. Careful sequence-based analysis of tRNAs can help to recognize this homoplasy, improving gene-order-based phylogenetic hypotheses and underscoring the importance of careful homology assessment. tRNA remolding also provides an additional mechanism by which gene order changes can occur within mtDNA: through the changing identity of tRNA genes themselves. Recognition of these remolding events can lead to new interpretations of gene order changes, as well as the discovery of phylogenetically relevant gene dynamics that are hidden at the level of gene order alone.

Project description:The mitochondrial genome (mitogenome) of Amblythyreus gestroi is described in the present paper. The complete mitogenome is a 15,228?bp circular DNA molecule, containing 13 protein-coding genes, 22 tRNA genes, two rRNA genes and a control region. Genome organization, nucleotide composition and codon usage of the mitogenome are noted, secondary structures of all tRNAs are predicted. The monophyly of Phymatinae is highly supported by the phylogenetic tree. Phylogenetic implications of the A. gestroi mitogenome is briefly discussed.

Project description:The complete mitochondrial genome (mitogenome) of the ambush bug, Carcinochelis bannaensis, was determined in this study. The sequenced mitogenome is a typical circular DNA molecule of 15,335?bp, containing 13 protein-coding genes, two rRNA genes, 22 tRNA genes and a putative control region. All protein-coding genes initiate with ATN codons and terminate with TAA codons except for COII,COIII and ND5 use a single T residue as the stop codon. All tRNAs have the clover-leaf structure except for the tRNASer(AGN) and the length of them range from 61 to 71?bp. The control region is 797?bp long with an A?+?T content of 66.3%. The phylogenetic analysis result supports the monophyly of Phymatinae.

Project description:Abstract Rhynocoris fuscipes (Fabricius 1787) is an important predator in China. In current study, the complete mitochondrial genome of R. fuscipes is determined. The mitogenome is 15,542 bp in size and comprises of 13 protein-coding genes, 22 transfer RNA genes, 2 ribosomal RNA genes, and a control region. Gene arrangement is identical to that of the putative ancestral arrangement of insects. All protein-coding genes initiate with ATN codons and terminate with TAA codons except for COII, ND4, and ND5 use TA or a single T residue as the termination codons. All tRNAs have the clover-leaf structure except for the tRNASer(AGN) and the length of them range from 62 to 70 bp. The phylogenetic result supports the monophyly of Harpactorinae and the sister relationship between R. fuscipes and Rhynocoris incertis.

Project description:The typical insect mitochondrial (mt) genome organization, which contains a single chromosome with 37 genes, was found in the infraorder Pentatomomorpha (suborder Heteroptera). The arrangement of mt genes in these true bugs is usually the same as the ancestral mt gene arrangement of insects. Rearrangement of transfer RNA (tRNA) genes, however, has been found in two subfamilies of flat bugs (Mezirinae and Calisiinae, family Aradidae). In this study, we sequenced the complete mt genomes of four species from three other subfamilies (Aradinae, Carventinae and Aneurinae). We found tRNA gene rearrangement in all of these four species. All of the rearranged tRNA genes are located between the mitochondrial control region and cox1, indicating this region as a hotspot for gene rearrangement in flat bugs; the rearrangement is likely caused by events of tandem duplication and random deletion of genes. Furthermore, our phylogenetic and dating analyses indicated that the swap of positions between trnQ and trnI occurred ~162 million years ago (MYA) in the most recent common ancestor of the five subfamilies of flat bugs investigated to date, whereas the swap of positions between trnC and trnW occurred later in the lineage leading to Calisiinae, and the translocation of trnC and trnY occurred later than 134 MYA in the lineage leading to Aradinae.

Project description:The complete mitochondrial genome (mitogenome) of the assassin bug, Reduvius gregoryi, was determined. The sequenced mitogenome is a typical circular DNA molecule of 16,477?bp, containing 13 protein-coding genes, 2 rRNA genes, 22 tRNA genes and a putative control region. Protein-coding genes all initiate with ATN codons and terminate with TAA codons except for ATP6, COI, COIII, ND4, and ND5 use a single T residue as the termination codon. All tRNAs have the clover-leaf structure except for the tRNASer(AGN) and the length of them range from 61 to 70?bp. The control region is 1731?bp long with an A?+?T content of 72.3%. Our phylogenetic analysis supported the polyphyly of Reduviinae and the sister relationship between Reduvius gregoryi and Reduvius tenebrosus.

Project description:The complete mitochondrial genome (mitogenome) of the assassin bug, Sycanus croceovittatus, was sequenced and analyzed in the present study. This mitogenome spans 15,644 bp in size with a high A + T content (71.7%), containing 13 protein-coding genes, 22 tRNA genes, 2 rRNA genes, and a putative control region. All protein-coding genes are initiated by ATN codons expect ND1 use GTG as start codons and terminated with TAG or TAA, expect COX3 use a single T-- residue as the stop codon. All tRNAs have the typical clover-leaf like structures except for tRNASer(AGN) . A phylogenetic analysis of S. croceovittatus and 33 other assassin bugs is also presented using 13 protein-coding genes and 2 rRNA genes. The result supports the monophyly of Harpactorinae and the sister relationship between S. croceovittatus and Agriosphodrus dohrni.

Project description:Mitochondrial DNA (mtDNA) is widely used to clarify phylogenetic relationships among and within species, and to determine population structure. Due to the linked nature of mtDNA genes it is expected that different genes will show similar results. Phylogenetic incongruence using mtDNA genes may result from processes such as heteroplasmy, nuclear integration of mitochondrial genes, polymerase errors, contamination, and recombination. In this study we used sequences from two mitochondrial genes (cytochrome b and cytochrome oxidase subunit I) from the wild vectors of Chagas disease, Triatoma eratyrusiformis and Mepraia species to test for topological congruence. The results showed some cases of phylogenetic incongruence due to misplacement of four haplotypes of four individuals. We discuss the possible causes of such incongruence and suggest that the explanation is an intra-individual variation likely due to heteroplasmy. This phenomenon is an independent evidence of common ancestry between these taxa.

Project description:Remolding of tRNAs is a well-documented process in mitochondrial genomes that changes the identity of a tRNA. It involves a duplication of a tRNA gene, a mutation that changes the anticodon and the loss of the ancestral tRNA gene. The net effect is a functional tRNA that is more closely related to tRNAs of a different alloacceptor family than to tRNAs with the same anticodon in related species. Beyond being of interest for understanding mitochondrial tRNA function and evolution, tRNA remolding events can lead to artifacts in the annotation of mitogenomes and thus in studies of mitogenomic evolution. Therefore, it is important to identify and catalog these events. Here we describe novel methods to detect tRNA remolding in large-scale data sets and apply them to survey tRNA remolding throughout animal evolution. We identify several novel remolding events in addition to the ones previously mentioned in the literature. A detailed analysis of these remoldings showed that many of them are derived from ancestral events.

Project description:The 16, 470 bp nucleotide sequence of the mitochondrial genome (mitogenome) of an assassin bug from the reduviid subfamily Harpactorinae, Agriosphodrus dohrni, has been revealed. The entire genome encodes for two ribosomal RNA genes (rrnL and rrnS), 22 transfer RNA (tRNA) genes, 13 protein-coding genes, and a control region. The nucleotide composition is biased toward adenine and thymine (A+T = 72.2%). Comparative analysis with two other reduviid species Triatoma dimidiata and Valentia hoffmanni, exhibited highly conserved genome architectures including genome contents, gene order, nucleotide composition, codon usage, amino acid composition, as well as genome asymmetry. All protein-coding genes use standard mitochondrial initiation codons (methionine and isoleucine), except that nad1 starts with GTG. All tRNAs have the classic clover-leaf structure, except that the dihydrouridine (DHU) arm of tRNA(Ser(AGN)) forms a simple loop. Secondary structure comparisons of the two mitochondrial ribosomal subunits among sequenced assassin bugs show that the sequence and structure of rrnL is more conservative than that of rrnS. The presence of structural elements in the control region is also discussed, with emphasis on their implications in the regulation of replication and/or transcription of the reduviid mitogenome. The phylogenetic analyses indicated that within Reduviidae, Harpactorinae is a sister group to the Salyavatinae + Triatominae clade.