Codon Positions Of Protein-coding Genes Research Articles

Phylogenetic inference of calyptrates, with the first mitogenomes for Gasterophilinae (Diptera: Oestridae) and Paramacronychiinae (Diptera: Sarcophagidae).

The complete mitogenome of the horse stomach bot fly Gasterophilus pecorum (Fabricius) and a near-complete mitogenome of Wohlfahrt's wound myiasis fly Wohlfahrtia magnifica (Schiner) were sequenced. The mitogenomes contain the typical 37 mitogenes found in metazoans, organized in the same order and orientation as in other cyclorrhaphan Diptera. Phylogenetic analyses of mitogenomes from 38 calyptrate taxa with and without two non-calyptrate outgroups were performed using Bayesian Inference and Maximum Likelihood. Three sub-analyses were performed on the concatenated data: (1) not partitioned; (2) partitioned by gene; (3) 3rd codon positions of protein-coding genes omitted. We estimated the contribution of each of the mitochondrial genes for phylogenetic analysis, as well as the effect of some popular methodologies on calyptrate phylogeny reconstruction. In the favoured trees, the Oestroidea are nested within the muscoid grade. Relationships at the family level within Oestroidea are (remaining Calliphoridae (Sarcophagidae (Oestridae, Pollenia + Tachinidae))). Our mito-phylogenetic reconstruction of the Calyptratae presents the most extensive taxon coverage so far, and the risk of long-branch attraction is reduced by an appropriate selection of outgroups. We find that in the Calyptratae the ND2, ND5, ND1, COIII, and COI genes are more phylogenetically informative compared with other mitochondrial protein-coding genes. Our study provides evidence that data partitioning and the inclusion of conserved tRNA genes have little influence on calyptrate phylogeny reconstruction, and that the 3rd codon positions of protein-coding genes are not saturated and therefore should be included.

Complete mitochondrial genome ofCamponotus atrox(Hymenoptera: Formicidae): a new tRNA arrangement in Hymenoptera

We sequenced the complete mitochondrial (mt) genome of Camponotus atrox (Hymenoptera: Formicidae), which is only distributed in Korea. The genome was 16 540 bp in size and contained typical sets of genes (13 protein-coding genes, 22 tRNAs, and 2 rRNAs). The C. atrox A+T-rich region, at 1402 bp, was the longest of all sequenced ant genomes and was composed of an identical tandem repeat consisting of six 100-bp copies and one 96-bp copy. A total of 315 bp of intergenic spacer sequence was spread over 23 regions. An alignment of the spacer sequences in ants was largely feasible among congeneric species, and there was substantial sequence divergence, indicating their potential use as molecular markers for congeneric species. The A/T contents at the first and second codon positions of protein-coding genes (PCGs) were similar for ant species, including C. atrox (73.9% vs. 72.3%, on average). With increased taxon sampling among hymenopteran superfamilies, differences in the divergence rates (i.e., the non-synonymous substitution rates) between the suborders Symphyta and Apocrita were detected, consistent with previous results. The C. atrox mt genome had a unique gene arrangement, trnI-trnM-trnQ, at the A+T-rich region and ND2 junction (underline indicates inverted gene). This may have originated from a tandem duplication of trnM-trnI, resulting in trnM-trnI-trnM-trnI-trnQ, and the subsequent loss of the first trnM and second trnI, resulting in trnI-trnM-trnQ.

Molecular phylogeny of the highly disjunct cliff water beetles from South Africa and China (Coleoptera: Aspidytidae)

The superfamily Dytiscoidea contains six families with an aquatic lifestyle, with most of its extant diversity in two families: the burrowing water beetles (Noteridae) and the diving beetles (Dytiscidae). The other families have few species (up to six) and generally highly disjunct extant distributions. Aspidytidae currently contains one genus with two species, one in China and one in South Africa. Here we provide the first molecular data for the Chinese species, allowing us to explore the phylogenetic relationships and position of both species of this small family for the first time. Based on a matrix of 11 genes we inferred a phylogenetic hypothesis for Dytiscoidea including all extant families. Unexpectedly, Aspidytidae were consistently recovered as paraphyletic relative to Amphizoidae, despite being well characterized by apparently synapomorphic adult features. A re-examination of larval characters in the two aspidytid species revealed that the larva of the Chinese species is strikingly similar to that of Amphizoidae. Both share a series of plesiomorphic features but also some potential synapomorphies, including a dense vestiture of short setae on the head capsule, anteriorly shifted posterior tentorial grooves and widely separated labial palps. Arguably these features may belong to the groundplan of the clade Aspidytidae+Amphizoidae, with far-reaching secondary modifications (including reversals) in the South African Aspidytes niobe. At present we retain the family Aspidytidae, however, due to the strong adult morphological synapomorphies of the two extant species, and the fact that the molecular paraphyly of the family may result from the highly divergent nature of the two extant species. This long evolutionary separation and strong divergence, in terms of gene sequences and larval features, is undeniable, substantial levels of saturation in third codon positions of protein-coding genes being present between the two taxa. We address this issue taxonomically by introducing the new genus Sinaspidytes gen. nov. for the Chinese Aspidytes wrasei. The continued contentious relationships amongst Dytiscidae, Hygrobiidae, Aspidytidae and Amphizoidae highlight the need for more data to address dytiscoid phylogenetics, possibly involving a genomic approach.(c) 2016 The Linnean Society of London

Phylogenetic relationship among some groups of orthopteran based on complete sequences of the mitochondrial <I>COI</I> gene

Complete sequences of the COI gene were used to reconstruct the phylogenetic relationship among 56 species from Orthoptera. We also analyzed the reliability of Orthoptera phylogenetic relationship using translated amino acid sequences of the COI genes. The COI sequences were divided into three data sets on the basis of different codon positions to calculate the Partitioned Bremer support (PBS), and to test the phylogenetic signal in different codon positions of protein-coding genes. The result supports the monophyly of Caelifera and Ensifera; but the monophyly of Acrididae, Catantopidae, Oedipodidae, Arcypteridae and Gomphoceridae are not supported. The P-distances among families vary from 0.107 to 0.153, which are smaller than those of other families, being consist with the classification that these 5 families should be merged into one family (Acrididae). Chrotogonidae and Pyrgomorphidae belong to the superfamily Pyrgomorphoidea. Pamphagidae should be a family alone consistent with Otte's taxonomic system. According to the PBS values, the 3rd and 1st codon positions contribution more for the Phylogenetic tree branches than the 2nd, and longer sequences contain more informative sites. We further demonstrated that it is feasible for phylogenetic studies at family level to use the genetic distances among COI sequences from different species of Orthopera.

A molecular phylogeny of Hemiptera inferred from mitochondrial genome sequences.

Classically, Hemiptera is comprised of two suborders: Homoptera and Heteroptera. Homoptera includes Cicadomorpha, Fulgoromorpha and Sternorrhyncha. However, according to previous molecular phylogenetic studies based on 18S rDNA, Fulgoromorpha has a closer relationship to Heteroptera than to other hemipterans, leaving Homoptera as paraphyletic. Therefore, the position of Fulgoromorpha is important for studying phylogenetic structure of Hemiptera. We inferred the evolutionary affiliations of twenty-five superfamilies of Hemiptera using mitochondrial protein-coding genes and rRNAs. We sequenced three mitogenomes, from Pyrops candelaria, Lycorma delicatula and Ricania marginalis, representing two additional families in Fulgoromorpha. Pyrops and Lycorma are representatives of an additional major family Fulgoridae in Fulgoromorpha, whereas Ricania is a second representative of the highly derived clade Ricaniidae. The organization and size of these mitogenomes are similar to those of the sequenced fulgoroid species. Our consensus phylogeny of Hemiptera largely supported the relationships (((Fulgoromorpha,Sternorrhyncha),Cicadomorpha),Heteroptera), and thus supported the classic phylogeny of Hemiptera. Selection of optimal evolutionary models (exclusion and inclusion of two rRNA genes or of third codon positions of protein-coding genes) demonstrated that rapidly evolving and saturated sites should be removed from the analyses.

Complete mitogenome sequence of the Chinese medaka Oryzias sinensis (Teleostei: Beloniformes) and its phylogenetic analysis

Chinese medaka Oryzias sinensis (Teleostei: Beloniformes) is distributed in China and the western areas of Korea. It differs from the Japanese medaka O. latipes in its morphology and biogeographical distribution in Korea. In this study, we analyzed the complete nucleotide sequence of the mitochondrial genome (mitogenome) of O. sinensis and determined its genomic structure. The complete mitogenome is a circular molecule of 16,654 bp and its structural organization is conserved across diverse vertebrate taxa. On a phylogenetic tree inferred from the nucleotide matrix, partitioned into four regions (i.e., the first and second codon positions of protein-coding genes, and the ribosomal RNA and transfer RNA genes), O. sinensis clustered consistently with O. latipes specimens from China and Korea, with a relatively short branch length, but was separated from O. latipes specimen from Japan. Our findings will allow the resolution of the taxonomic problems of closely related Oryzias species, such as O. sinensis and O. latipes in a future study.

Exploring Patterns and Extent of Bias in Estimating Divergence Time from Mitochondrial DNA Sequence Data in a Particular Lineage: A Case Study of Salamanders (Order Caudata)

In the practice of molecular dating, substitution saturation will bias the results if not properly modeled. Date estimates based on commonly used mitochondrial DNA sequences likely suffer from this problem because of their high substitution rate. Nevertheless, the patterns and extent of such expected bias remain unknown for many major evolutionary lineages, which often differ in ages, available calibrations, and substitution rates of their mitochondrial genome. In this case study of salamanders, we used estimates based on multiple nuclear exons to assess the effects of saturation on dating divergences using mitochondrial genome sequences on a timescale of ~200-300 My. The results indicated that, due to saturation for older divergences and in the absence of younger effective calibration points, dates derived from the mitochondrial data were considerably overestimated and systematically biased toward the calibration point for the ingroup root. The overestimate might be as great as 3-10 times (about 20 My) older than actual divergence dates for recent splitting events and 40 My older for events that are more ancient. For deep divergences, dates estimated were strongly compressed together. Furthermore, excluding the third codon positions of protein-coding genes or only using the RNA genes or second codon positions did not considerably improve the performance. In the order Caudata, slowly evolving markers such as nuclear exons are preferred for dating a phylogeny covering a relatively wide time span. Dates estimated from these markers can be used as secondary calibrations for dating recent events based on rapidly evolving markers for which mitochondrial DNA sequences are attractive candidates due to their short coalescent time. In other groups, similar evaluation should be performed to facilitate the choice of markers for molecular dating and making inferences from the results.

Mutation and Selection on the Wobble Nucleotide in tRNA Anticodons in Marine Bivalve Mitochondrial Genomes

BackgroundAnimal mitochondrial genomes typically encode one tRNA for each synonymous codon family, so that each tRNA anticodon essentially has to wobble to recognize two or four synonymous codons. Several factors have been hypothesized to determine the nucleotide at the wobble site of a tRNA anticodon in mitochondrial genomes, such as the codon-anticodon adaptation hypothesis, the wobble versatility hypothesis, the translation initiation and elongation conflict hypothesis, and the wobble cost hypothesis.Principal FindingsIn this study, we analyzed codon usage and tRNA anticodon wobble sites of 29 marine bivalve mitochondrial genomes to evaluate features of the wobble nucleotides in tRNA anticodons. The strand-specific mutation bias favors G and T on the H strand in all the 29 marine bivalve mitochondrial genomes. A bias favoring G and T is also visible in the third codon positions of protein-coding genes and the wobble sites of anticodons, rejecting that codon usage bias drives the wobble sites of tRNA anticodons or tRNA anticodon bias drives the evolution of codon usage. Almost all codon families (98.9%) from marine bivalve mitogenomes support the wobble versatility hypothesis. There are a few interesting exceptions involving tRNATrp with an anticodon CCA fixed in Pectinoida species, tRNASer with a GCU anticodon fixed in Mytiloida mitogenomes, and the uniform anticodon CAU of tRNAMet translating the AUR codon family.Conclusions/SignificanceThese results demonstrate that most of the nucleotides at the wobble sites of tRNA anticodons in marine bivalve mitogenomes are determined by wobble versatility. Other factors such as the translation initiation and elongation conflict, and the cost of wobble translation may contribute to the determination of the wobble nucleotide in tRNA anticodons. The finding presented here provides valuable insights into the previous hypotheses of the wobble nucleotide in tRNA anticodons by adding some new evidence.