The complete mitochondrial genome of the Sichuan taimen (Hucho bleekeri): repetitive sequences in the control region and phylogenetic implications for Salmonidae

The complete mitochondrial DNA genome of the Sichuan taimen (Hucho bleekeri) was determined by the long and accurate polymerase chain reaction (LA-PCR) and primer walking sequence method. The entire mitochondrial genome of this species is 16,997 bp in length, making it the longest among the completely sequenced Salmonidae mitochondrial genomes. It consists of two ribosomal RNA (rRNA) genes, 13 protein-coding genes, 22 transfer RNA (tRNA) genes, and one control region (CR). The gene arrangement, nucleotide composition, and codon usage pattern of the mitochondrial genome are similar to those of other teleosts. A T-type mononucleotide microsatellite and an 82 bp tandem repeat were identified in the control region, which were almost identical among the three H. bleekeri individuals examined. Both phylogenetic analyses based on 12 concatenated protein-coding genes of the heavy strand and on just the control region show that H. bleekeri is a basal species in Salmoninae. In addition, Salmo, Salvelinus and Oncorhynchus all represent monophyletic groups, respectively. All freshwater species occupied basal phylogenetic positions, and also possessed various tandem repeats in their mitochondrial control regions. These results support established phylogenetic relationships among genera in Salmonidae based on morphological and molecular analyses, and are consistent with the hypothesis that Salmonidae evolved from freshwater species.     

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.     

The mitochondrial genome sequence of the scorpion Centruroides limpidus (Karsch 1879) (Chelicerata; Arachnida)

The mitochondrial genome of the scorpion Centruroides limpidus (Chelicerata; Arachnida) has been completely sequenced and is 14519 bp long. The genome contains 13 protein-encoding genes, two ribosomal RNA genes, 21 transfer RNA genes and a large non-coding region related to the control region. The overall A + T composition is the lowest among the complete mitochondrial sequences published within the Chelicerata subphylum. Gene order and gene content differ slightly from that of Limulus polyphemus (Chelicerata: Xiphosura): i.e., the lack of the trnD gene, and the translocation–inversion of the trnI gene. Preliminary phylogenetic analysis of some Chelicerata shows that scorpions (C. limpidus and Mesobuthus gibbosus) make a tight cluster with the spiders (Arachnida; Araneae). Our analysis does not support that Scorpiones order is the sister group to all Arachnida Class, since it is closer to Araneae than to Acari orders.     

Three LIF-dependent signatures and gene clusters with atypical expression profiles, identified by transcriptome studies in mouse ES cells and early derivatives

Background

The apparent scarcity of available sequence data has greatly impeded evolutionary studies in Acari (mites and ticks). This subclass encompasses over 48,000 species and forms the largest group within the Arachnida. Although mitochondrial genomes are widely utilised for phylogenetic and population genetic studies, only 20 mitochondrial genomes of Acari have been determined, of which only one belongs to the diverse order of the Sarcoptiformes. In this study, we describe the mitochondrial genome of the European house dust mite Dermatophagoides pteronyssinus, the most important member of this largely neglected group.

Results

The mitochondrial genome of D. pteronyssinus is a circular DNA molecule of 14,203 bp. It contains the complete set of 37 genes (13 protein coding genes, 2 rRNA genes and 22 tRNA genes), usually present in metazoan mitochondrial genomes. The mitochondrial gene order differs considerably from that of other Acari mitochondrial genomes. Compared to the mitochondrial genome of Limulus polyphemus, considered as the ancestral arthropod pattern, only 11 of the 38 gene boundaries are conserved. The majority strand has a 72.6% AT-content but a GC-skew of 0.194. This skew is the reverse of that normally observed for typical animal mitochondrial genomes. A microsatellite was detected in a large non-coding region (286 bp), which probably functions as the control region. Almost all tRNA genes lack a T-arm, provoking the formation of canonical cloverleaf tRNA-structures, and both rRNA genes are considerably reduced in size. Finally, the genomic sequence was used to perform a phylogenetic study. Both maximum likelihood and Bayesian inference analysis clustered D. pteronyssinus with Steganacarus magnus, forming a sistergroup of the Trombidiformes.

Conclusion

Although the mitochondrial genome of D. pteronyssinus shares different features with previously characterised Acari mitochondrial genomes, it is unique in many ways. Gene order is extremely rearranged and represents a new pattern within the Acari. Both tRNAs and rRNAs are truncated, corroborating the theory of the functional co-evolution of these molecules. Furthermore, the strong and reversed GC- and AT-skews suggest the inversion of the control region as an evolutionary event. Finally, phylogenetic analysis using concatenated mt gene sequences succeeded in recovering Acari relationships concordant with traditional views of phylogeny of Acari.     

The first complete mitochondrial genome sequence of Nanorana parkeri and Nanorana ventripunctata (Amphibia: Anura: Dicroglossidae), with related phylogenetic analyses

Members of the Nanorana genus (family Dicroglossidae) are often referred to as excellent model species with which to study amphibian adaptations to extreme environments and also as excellent keystone taxa for providing insights into the evolution of the Dicroglossidae. However, a complete mitochondrial genome is currently only available for Nanorana pleskei. Thus, we analyzed the complete mitochondrial genomes of Nanorana parkeri and Nanorana ventripunctata to investigate their evolutionary relationships within Nanorana and their phylogenetic position in the family Dicroglossidae. Our results showed that the genomes of N. parkeri (17,837 bp) and N. ventripunctata (18,373 bp) encode 13 protein‐coding genes (PCGs), two ribosomal RNA genes, 23 transfer RNA (tRNA) genes, and a noncoding control region. Overall sequences and genome structure of the two species showed high degree of similarity with N. pleskei, although the motif structures and repeat sequences of the putative control region showed clear differences among these three Nanorana species. In addition, a tandem repeat of the tRNA‐Met gene was found located between the tRNA‐Gln and ND2 genes. On both the 5′ and 3′‐sides, the control region possessed distinct repeat regions; however, the CSB‐2 motif was not found in N. pleskei. Based on the nucleotide sequences of 13 PCGs, our phylogenetic analyses, using Bayesian inference and maximum‐likelihood methods, illustrate the taxonomic status of Nanorana with robust support showing that N. ventripunctata and N. pleskei are more closely related than they are to N. parkeri. In conclusion, our analyses provide a more robust and reliable perspective on the evolutionary history of Dicroglossidae than earlier analyses, which used only a single species (N. pleskei).     

The complete mitochondrial genome of Accipiter virgatus and evolutionary history of the pseudo-control regions in Falconiformes

The complete mitochondrial genome sequence of Accipiter virgatus was determined. This mt-genome was 17,952 bp in length and consisted of 22 tRNA genes, 13 protein-coding genes, 2 rRNA genes, one control region (CR) and one pseudo-control region (CCR). Phylogenetic analyses of 14,644 bp of mitochondrial DNA (12 protein-coding genes, 2 rRNAs and 22 tRNAs) revealed the phylogenetic position of Cathartidae (Cathartes aura) was more closer to Ciconiidae (storks) than Accipitridae. To investigate the divergence times of the CCRs in Falconiformes, detailed analyses of the noncoding regions (CR and CCR) were performed. We found the recently reported novel gene order in Falconiformes had multiple independent origins and hence cannot be used to infer phylogenetic lineages. Indeed, the molecular clock suggested the CCR in Falconidae emerged about 65.4 million years (Mya), while that in Pandionidae–Accipitridae clade emerged about 19.16 Mya. The intra-genomic homology between the noncoding regions was detected in Spilornis cheela, which supporting the duplication hypothesis. Furthermore, the structure of CCR should be featured by a region containing tandem repeats as two definitely separated clusters of tandem repeats were found. The findings presented here should be considered in future phylogenetic and evolutionary studies targeting the pseudo-control regions of all Falconiformes species.     

Complete mitochondrial genome of Tubulipora flabellaris (Bryozoa: Stenolaemata): the first representative from the class Stenolaemata with unique gene order

Mitochondrial genomes play a significant role in the reconstruction of phylogenetic relationships within metazoans. There are still many controversies concerning the phylogenetic position of the phylum Bryozoa. In this research, we have finished the complete mitochondrial genome of one bryozoan (Tubulipora flabellaris), which is the first representative from the class Stenolaemata. The complete mitochondrial genome of T. flabellaris is 13,763 bp in length and contains 36 genes, which lacks the atp8 gene in contrast to the typical metazoan mitochondrial genomes. Gene arrangement comparisons indicate that the mitochondrial genome of T. flabellaris has unique gene order when compared with other metazoans. The four known bryozoans complete mitochondrial genomes also have very different gene arrangements, indicates that bryozoan mitochondrial genomes have experienced drastic rearrangements. To investigate the phylogenetic relationship of Bryozoa, phylogenetic analyses based on amino acid sequences of 11 protein coding genes (excluding atp6 and atp8) from 26 metazoan complete mitochondrial genomes were made utilizing Maximum Likelihood (ML) and Bayesian methods, respectively. The results indicate the monopoly of Lophotrochozoa and a close relationship between Chaetognatha and Bryozoa. However, more evidences are needed to clarify the relationship between two groups. Lophophorate appeared to be polyphyletic according to our analyses. Meanwhile, neither analysis supports close relationship between Branchiopod and Phoronida. Four bryozoans form a clade and the relationship among them is T. flabellaris + (F. hispida + (B. neritina + W. subtorquata)), which is in coincidence with traditional classification system.     

The complete mitochondrial genomes of two schizothoracine fishes (Teleostei,Cypriniformes): A novel minisatellite in fish mitochondrial genomes

Minisatellites, a class of variable number tandem repeats (VNTRs), are abundant throughout the control region in animal mitochondrial DNA (mtDNA) but rare in other regions of animal mtDNA. Here, we reported a novel minisatellite in fish mitochondrial genomes. We first determined the complete mitochondrial genomes of two schizothoracine fishes (Herzensteinia microcephalus and Schizopygopsis pylzovi) and found a type of minisatellites in a novel region between the tRNA‐Thr and tRNA‐Pro genes in their mtDNA. To explore the origin and evolution of the minisatellites in different schizothoracine and closely related fishes, we analyzed the available 80 fish mitogenomes which represent five closely related tribes of cyprinine fishes. The results from the phylogenetic analyses show that the schizothoracine fishes sensu stricto is not a monophyletic group and is divided into two clades (Schizothoracini and Schizopygopsini); and the minisatellite is only present in Schizopygopsini distributed in the region between the two tRNA genes (tRNA‐Thr and tRNA‐Pro) of the mtDNA. This is the first record of a minisatellite in a non‐control region of fish mitogenome.     

First Sequenced Mitochondrial Genome from the Phylum Acanthocephala(Leptorhynchoides thecatus) and Its Phylogenetic Position Within Metazoa

The complete sequence of the mitochondrial genome of Leptorhynchoides thecatus (Acanthocephala) was determined, and a phylogenetic analysis was carried out to determine its placement within Metazoa. The genome is circular, 13,888 bp, and contains at least 36 of the 37 genes typically found in animal mitochondrial genomes. The genes for the large and small ribosomal RNA subunits are shorter than those of most metazoans, and the structures of most of the tRNA genes are atypical. There are two significant noncoding regions (377 and 294 bp), which are the best candidates for a control region; however, these regions do not appear similar to any of the control regions of other animals studied to date. The amino acid and nucleotide sequences of the protein coding genes of L. thecatus and 25 other metazoan taxa were used in both maximum likelihood and maximum parsimony phylogenetic analyses. Results indicate that among taxa with available mitochondrial genome sequences, Platyhelminthes is the closest relative to L. thecatus, which together are the sister taxon of Nematoda; however, long branches and/or base composition bias could be responsible for this result. The monophyly of Ecdysozoa, molting organisms, was not supported by any of the analyses. This study represents the first mitochondrial genome of an acanthocephalan to be sequenced and will allow further studies of systematics, population genetics, and genome evolution.Reviewing Editor: Dr. Rafael Zardoya The entire genome sequence has been deposited with the GenBank Data Libraries under-accession number AY562383.     

The first complete mitochondrial genome of the Indian Tent Turtle,Pangshura tentoria (Testudines: Geoemydidae): Characterization and comparative analysis

The characterization of a complete mitogenome is widely used in genomics studies for systematics and evolutionary research. However, the sequences and structural motifs contained within the mitogenome of Testudines taxa have rarely been examined. The present study decodes the first complete mitochondrial genome of the Indian Tent Turtle, Pangshura tentoria (16,657 bp) by using next‐generation sequencing. This denovo assembly encodes 37 genes: 13 protein‐coding genes (PCGs), 22 transfer RNA (tRNAs), two ribosomal RNA, and one control region (CR). Most of the genes were encoded on majority strand, except for one PCG (NADH dehydrogenase subunit 6) and eight tRNAs. Most of the PCGs were started with an ATG initiation codon, except for Cytochrome oxidase subunit 1 with “GTG” and NADH dehydrogenase subunit 5 with “ATA.” The termination codons, “TAA” and “AGA” were observed in two subunits of NADH dehydrogenase gene. The relative synonymous codon usage analysis revealed the maximum abundance of alanine, isoleucine, leucine, and threonine. The nonsynonymous/synonymous ratios were <1 in all PCGs, which indicates strong negative selection among all Geoemydid species. The study also found the typical cloverleaf secondary structure in most of the tRNA genes, except for serine with the lack of the conventional DHU arm. The comparative study of Geoemydid mitogenomes revealed the occurrence of tandem repeats was frequent in the 3′ end of CR. Further, two copies of a unique tandem repeat “TTCTCTTT” were identified in P. tentoria. The Bayesian and maximum‐likelihood phylogenetic trees using concatenation of 13 PCGs revealed the close relationships of P. tentoria with Batagur trivittata in the studied dataset. All the Geoemydid species showed distinct clustering with high bootstrap support congruent with previous evolutionary hypotheses. We suggest that the generations of more mitogenomes of Geoemydid species are required, to improve our understanding of their in‐depth phylogenetic and evolutionary relationships.     

Cloning and characterization of a microsatellite in the mitochondrial control region of the African side-necked turtle,Pelomedusa subrufa

The nucleotide sequence of the African side-necked turtle mitochondrial control region and its flanking tRNA genes was determined. This 73% A+T-rich region is 1194 bp long. Several conserved motifs involved in the regulation of the mitochondrial genome replication process, including one conserved sequence block (CSB1), and three termination-associated sequences were identified. The most remarkable feature found in this control region was the presence of six microsatellite-containing tandem repeats between the CSB1 motif and the tRNA^Phe gene. The potential usefulness of this microsatellite sequence for population-level studies is enhanced by its unique localization in the maternally inherited mitochondrial molecule.     

Complete mitochondrial genome sequences of the Arctic Ocean codfishes <Emphasis Type="Italic">Arctogadus glacialis</Emphasis> and <Emphasis Type="Italic">Boreogadus saida</Emphasis> reveal oriL and tRNA gene duplications

We have determined the complete mitochondrial genome sequences of the codfishes Arctogadus glacialis and Boreogadus saida (Order Gadiformes, Family Gadidae). The 16,644 bp and 16,745 bp mtDNAs, respectively, contain the same set of 37 structural genes found in all vertebrates analyzed so far. The gene organization is conserved compared to other Gadidae species, but with one notable exception. B. saida contains heteroplasmic rearrangement-mediated duplications that include the origin of light-strand replication and nearby tRNA genes. Examination of the mitochondrial control region of A. glacialis, B. saida, and four additional representative Gadidae genera identified a highly variable domain containing tandem repeat motifs in A. glacialis. Mitogenomic phylogeny based on the complete mitochondrial genome sequence, the concatenated protein-coding genes, and the derived protein sequences strongly supports a sister taxa affiliation of A. glacialis and B. saida.     

Complete mitochondrial genome sequence of the Himalayan Griffon,Gyps himalayensis (Accipitriformes: Accipitridae): Sequence,structure, and phylogenetic analyses

This is the first study to describe the mitochondrial genome of the Himalayan Griffon, Gyps himalayensis, which is an Old World vulture belonging to the family Accipitridae and occurring along the Himalayas and the adjoining Tibetan Plateau. Its mitogenome is a closed circular molecule 17,381 bp in size containing 13 protein‐coding genes, 22 tRNA coding genes, two rRNA‐coding genes, a control region (CR), and an extra pseudo‐control region (CCR) that are conserved in most Accipitridae mitogenomes. The overall base composition of the G. himalayensis mitogenome is 24.55% A, 29.49% T, 31.59% C, and 14.37% G, which is typical for bird mitochondrial genomes. The alignment of the Accipitridae species control regions showed high levels of genetic variation and abundant AT content. At the 5′ end of the domain I region, a long continuous poly‐C sequence was found. Two tandem repeats were found in the pseudo‐control regions. Phylogenetic analysis with Bayesian inference and maximum likelihood based on 13 protein‐coding genes indicated that the relationships at the family level were (Falconidae + (Cathartidae + (Sagittariidae + (Accipitridae + Pandionidae))). In the Accipitridae clade, G. himalayensis is more closely related to Aegypius monachus than to Spilornis cheela. The complete mitogenome of G. himalayensis provides a potentially useful resource for further exploration of the taxonomic status and phylogenetic history of Gyps species.     

Mitochondrial DNA Sequence and Gene Organization in the Australian Blacklip Abalone Haliotis rubra (Leach)

The complete mitochondrial DNA of the blacklip abalone Haliotis rubra (Gastropoda: Mollusca) was cloned and 16,907 base pairs were sequenced. The sequence represents an estimated 99.85% of the mitochondrial genome, and contains 2 ribosomal RNA, 22 transfer RNA, and 13 protein-coding genes found in other metazoan mtDNA. An AT tandem repeat and a possible C-rich domain within the putative control region could not be fully sequenced. The H. rubra mtDNA gene order is novel for mollusks, separated from the black chiton Katharina tunicata by the individual translocations of 3 tRNAs. Compared with other mtDNA regions, sequences from the ATP8, NAD2, NAD4L, NAD6, and 12S rRNA genes, as well as the control region, are the most variable among representatives from Mollusca, Arthropoda, and Rhynchonelliformea, with similar mtDNA arrangements to H. rubra. These sequences are being evaluated as genetic markers within commercially important Haliotis species, and some applications and considerations for their use are discussed. An erratum to this article is available at.     

The complete mitochondrial genome of the marbled rockfish <Emphasis Type="Italic">Sebastiscus marmoratus</Emphasis> (Scorpaeniformes,Scorpaenidae): Genome characterization and phylogenetic considerations

The complete mitochondrial genome sequence of the marbled rockfish Sebastiscus marmoratus (Scorpaeniformes, Scorpaenidae) was determined and phylogenetic analysis was conducted to elucidate the evolutionary relationship of the marbled rockfish with other Sebastinae species. This mitochondrial genome, consisting of 17301 bp, is highly similar to that of most other vertebrates, containing the same gene order and an identical number of genes or regions, including 13 protein-coding genes, two ribosomal RNAs, 22 transfer RNAs, and one putative control region. Most of the genes are encoded on the H-strand, while the ND6 and seven tRNA genes (for Gln, Ala, Asn, Tyr, Ser (UCA), Glu, and Pro) are encoded on the L-strand. The reading frame of two pairs of genes overlapped on the same strand (the ATPase 8 and 6 genes overlapped by ten nucleotides; ND4L and ND4 genes overlapped by seven nucleotides). The possibly nonfunctional light-strand replication origin folded into a typical stem-loop secondary structure and a conserved motif (5′-GCCGG-3′) was found at the base of the stem within the tRNA^Cys gene. An extent termination-associated sequence (ETAS) and conserved sequence blocks (CSB) were identified in the control region, except for CSB-1; unusual long tandem repeats were found at the 3′ end of the control region. Phylogenetic analyses supported the view that Sebastinae comprises four genera (Sebastes, Hozukius, Helicolenus, and Sebastiscus).     

红足壮异蝽Urochela quadrinotata Reuter线粒体基因组的测定与分析

研究测定并分析了红足壮异蝽Urochela quadrinotata Reuter的线粒体基因组全序列。该线粒体基因组全长16585bp(GenBank登录号为JQ743678),A+T含量为75.4%,共编码35个基因,包括13个蛋白质基因、20个tRNA基因(两个tRNA基因,即tRNAIle和tRNAGln未被检测到)、2个rRNA基因及一段较长的非编码区(控制区,亦称A+T富含区)。基因排序与大部分昆虫的线粒体基因排列方式相同,没有发生基因重排。除tRNASer(AGN)的DHU臂无法形成典型的茎环结构,其余tRNA基因均能稳定形成典型的三叶草二级结构。预测了红足壮异蝽16S和12S rRNA的二级结果,分别包括6个结构域43个茎环和3个结构域27茎环。控制区含一个长1652bp的串联重复区域,由16个串联重复单元组成。     

Complete DNA sequence of the mitochondrial genome ofCepaea nemoralis (Gastropoda: Pulmonata)

The nucleotide sequence of a mitochondrial genome of the pulmonate gastropod molluscCepaea nemoralis has been determined. Contained within the 14,100 basepairs (bp) are the two ribosomal RNA genes and 13 protein coding genes typical of metazoan mitochondrial genomes. TheCepaea mtDNA does contain a gene for ATPase subunit 8, like the clausiliid pulmonate,Albinaria, and the chiton,Katharina, but unlike the bivalve mollusc,Mytilus. The mitochondrial genetic code ofCepaea is proposed to be the same as that ofMytilus, Katharina, andDrosophila. Only 14 putative tRNA genes are presented, although there is sufficient unassigned sequence to encode the remainder of the expected total of 22 tRNA genes. These 14 tRNA genes are a mixture of standard cloverleaf structures and nonstandard structures containing TV replacement loops as seen in nematode and mosquito mitochondrial genomes. If the eight unidentified tRNA genes are indeed present, very little unassigned sequence would remain to serve as a control region. Genes are transcribed from both strands of the molecule. Base composition is the least biased for any reported animal mitochondrial genome and is also very little skewed between strands using measures independent of base composition. TheCepaea mitochondrial gene order is quite unlike that of any other reported metazoan mtDNA, with the exception of the recently reported partial sequences ofAlbinaria. No gene bound-aries are shared among all the reported molluscan taxa, demonstrating a complete lack of conservation of mitochondrial gene order across the phylum Mollusca.     

Comparative Mitogenomics of the Assassin Bug Genus Peirates (Hemiptera: Reduviidae: Peiratinae) Reveal Conserved Mitochondrial Genome Organization of P. atromaculatus,P. fulvescens and P. turpis

In this study, we sequenced four new mitochondrial genomes and presented comparative mitogenomic analyses of five species in the genus Peirates (Hemiptera: Reduviidae). Mitochondrial genomes of these five assassin bugs had a typical set of 37 genes and retained the ancestral gene arrangement of insects. The A+T content, AT- and GC-skews were similar to the common base composition biases of insect mtDNA. Genomic size ranges from 15,702 bp to 16,314 bp and most of the size variation was due to length and copy number of the repeat unit in the putative control region. All of the control region sequences included large tandem repeats present in two or more copies. Our result revealed similarity in mitochondrial genomes of P. atromaculatus, P. fulvescens and P. turpis, as well as the highly conserved genomic-level characteristics of these three species, e.g., the same start and stop codons of protein-coding genes, conserved secondary structure of tRNAs, identical location and length of non-coding and overlapping regions, and conservation of structural elements and tandem repeat unit in control region. Phylogenetic analyses also supported a close relationship between P. atromaculatus, P. fulvescens and P. turpis, which might be recently diverged species. The present study indicates that mitochondrial genome has important implications on phylogenetics, population genetics and speciation in the genus Peirates.     

Two novel mitogenomes of Dipodidae species and phylogeny of Rodentia inferred from the complete mitogenomes

Two novel mitogenomes of Eozapus setchuanus (KJ648495) and Sicista concolor (KJ648496) were reported and their total lengths were 16,630 bp and 16,493 bp, respectively. Both mitogenomes which were analogous to other rodent mitogenomes, contained 13 protein-coding genes, 22 tRNAs, 2 rRNAs, and a control region. Specifically, the ND2 gene of S. concolor has three amino acids lesser than that of two other Dipodidae species (E. setchuanus and Jaculus jaculus) due to a premature termination codon in the 3′ end. We detected a tandem repeat cluster of 221 bp and 274 bp in the control region of S. concolor and E. setchuanus, respectively. Along with phylogenetic relationship analysis, we speculated that the tandem repeats in control regions might be common in Dipodinae species. Our phylogenetic analysis using concatenated mitochondrial gene datasets suggested five suborder and 16 family monophyletic groups in 54 rodent taxa sampled and strongly supported a basal position of the squirrel-related clade (PP = 1; BP = 100). Dipodidae had a sister-group relationship with Muroidea, and Sicistinae was in the base of Dipodidae clade. The complete mitochondrial genomes showed high resolution in deep-level phylogenetic relationship reconstructions of Rodentia.