Complete Mitochondrial Genome Sequences of the South American and the Australian Lungfish: Testing of the Phylogenetic Performance of Mitochondrial Data Sets for Phylogenetic Problems in Tetrapod Relationships

We determined the complete nucleotide sequences (16403 and 16572 base pairs, respectively) of the mitochondrial genomes of the South American lungfish, Lepidosiren paradoxa, and the Australian lungfish, Neoceratodus forsteri (Sarcopterygii, Dipnoi). The mitochondrial DNA sequences were established in an effort to resolve the debated evolutionary positions of the lungfish and the coelacanth relative to land vertebrates. Previous molecular phylogenetic studies based on complete mtDNA sequences, including only the African lungfish, Protopterus dolloi, sequence were able to strongly reject the traditional textbook hypothesis that coelacanths are the closest relatives of land vertebrates. However, these studies were unable to statistically significantly distinguish between the two remaining scenarios: lungfish as the closest relatives to land vertebrates and lungfish and coelacanths jointly as their sister group (Cao et al. 1998; Zardoya et al. 1998; Zardoya and Meyer 1997a). Lungfish, coelacanths, and the fish ancestors of the tetrapod lineage all originated within a short time window of about 20 million years, back in the early Devonian (about 380 to 400 million years ago). This short divergence time makes the determination of the phylogenetic relationships among these three lineages difficult. In this study, we attempted to break the long evolutionary branch of lungfish, in an effort to better resolve the phylogenetic relationships among the three extant sarcopterygian lineages. The gene order of the mitochondrial genomes of the South American and Australian lungfish conforms to the consensus gene order among gnathostome vertebrates. The phylogenetic analyses of the complete set of mitochondrial proteins (without ND6) suggest that the lungfish are the closest relatives of the tetrapods, although the support in favor of this scenario is not statistically significant. The two other smaller data sets (tRNA and rRNA genes) give inconsistent results depending on the different reconstruction methods applied and cannot significantly rule out any of the three alternative hypotheses. Nuclear protein-coding genes, which might be better phylogenetic markers for this question, support the lungfish–tetrapod sister-group relationship (Brinkmann et al. 2004).This article contains online supplementary material.Reviewing Editor: Dr. Rafael Zardoya     

The Complete Mitochondrial DNA Sequence of the Bichir (Polypterus Ornatipinnis), a Basal Ray-Finned Fish: Ancient Establishment of the Consensus Vertebrate Gene Order

The evolutionary position of bichirs is disputed, and they have been variously aligned with ray-finned fish (Actinopterygii) or lobe-finned fish (Sarcopterygii), which also include tetrapods. Alternatively, they have been placed into their own group, the Brachiopterygii. The phylogenetic position of bichirs as possibly the most primitive living bony fish (Osteichthyes) made knowledge about their mitochondrial genome of considerable evolutionary interest. We determined the complete nucleotide sequence (16,624 bp) of the mitochondrial genome of a bichir, Polypterus ornatipinnis. Its genome contains 13 protein-coding genes, 22 tRNAs, two rRNAs and one major noncoding region. The genome''s structure and organization show that this is the most basal vertebrate that conforms to the consensus vertebrate mtDNA gene order. Bichir mitochondrial protein-coding and ribosomal RNA genes have greater sequence similarity to ray-finned fish than to either lamprey or lungfish. Phylogenetic analyses suggest the bichir''s placement as the most basal living member of the ray-finned fish and rule out its classification as a lobe-finned fish. Hence, its lobe-fins are probably not a shared-derived trait with those of lobe-finned fish (Sarcopterygii).     

The Complete DNA Sequence of the Mitochondrial Genome of a ``living Fossil,'''' the Coelacanth (Latimeria Chalumnae)

The complete nucleotide sequence of the 16,407-bp mitochondrial genome of the coelacanth (Latimeria chalumnae) was determined. The coelacanth mitochondrial genome order is identical to the consensus vertebrate gene order which is also found in all ray-finned fishes, the lungfish, and most tetrapods. Base composition and codon usage also conform to typical vertebrate patterns. The entire mitochondrial genome was PCR-amplified with 24 sets of primers that are expected to amplify homologous regions in other related vertebrate species. Analyses of the control region of the coelacanth mitochondrial genome revealed the existence of four 22-bp tandem repeats close to its 3' end. The phylogenetic analyses of a large data set combining genes coding for rRNAs, tRNAs, and proteins (16,140 characters) confirmed the phylogenetic position of the coelacanth as a lobe-finned fish; it is more closely related to tetrapods than to ray-finned fishes. However, different phylogenetic methods applied to this largest available molecular data set were unable to resolve unambiguously the relationship of the coelacanth to the two other groups of extant lobe-finned fishes, the lungfishes and the tetrapods. Maximum parsimony favored a lungfish/coelacanth or a lungfish/tetrapod sistergroup relationship depending on which transversion:transition weighting is assumed. Neighbor-joining and maximum likelihood supported a lungfish/tetrapod sistergroup relationship.     

Searching for the closest living relative(s) of tetrapods through evolutionary analyses of mitochondrial and nuclear data

The phylogenetic relationships of the African lungfish (Protopterus dolloi) and the coelacanth (Latimeria chalumnae) with respect to tetrapods were analyzed using complete mitochondrial genome DNA sequences. A lungfish + coelancanth clade was favored by maximum parsimony (although this result is dependent on which transition:transversion weights are applied), and a lungfish + tetrapod clade was supported by neighbor-joining and maximum-likelihood analyses. These two hypotheses received the strongest statistical and bootstrap support to the exclusion of the third alternative, the coelacanth + tetrapod sister group relationship. All mitochondrial protein coding genes combined favor a lungfish + tetrapod grouping. We can confidently reject the hypothesis that the coelacanth is the closest living relative of tetrapods. When the complete mitochondrial sequence data were combined with nuclear 28S rRNA gene data, a lungfish + coelacanth clade was supported by maximum parsimony and maximum likelihood, but a lungfish + tetrapod clade was favored by neighbor-joining. The seeming conflicting results based on different data sets and phylogenetic methods were typically not statistically strongly supported based on Kishino-Hasegawa and Templeton tests, although they were often supported by strong bootstrap values. Differences in rate of evolution of the different mitochondrial genes (slowly evolving genes such as the cytochrome oxidase and tRNA genes favored a lungfish + coelacanth clade, whereas genes of relatively faster substitution rate, such as several NADH dehydrogenase genes, supported a lungfish + tetrapod grouping), as well as the rapid radiation of the lineages back in the Devonian, rather than base compositional biases among taxa seem to be directly responsible for the remaining uncertainty in accepting one of the two alternate hypotheses.     

Complete nucleotide sequence of Japanese flounder (Paralichthys olivaceus) mitochondrial genome: structural properties and cue for resolving teleostean relationships

We cloned and sequenced the complete mitochondrial genome of Japanese flounder (Paralichthys olivaceus). A circular 17,090 bp mitochondrial genome from the flounder contains 37 structural genes as in other vertebrates so far reported. This is the first report of the complete mitochondrial sequence from a higher teleostean fish (Acanthopterygii). The organization including gene order is quite similar to that of other teleostean fishes as well as placental mammals. The putative control region of the Japanese flounder mitochondrial genome contains a length variable region of about a 74 bp tandem repeat cluster. As a preliminary study we adopted the maximum likelihood and neighbor-joining inference methods to examine phylogenetic relationships among teleostean and related fishes. Comparisons of amino acid sequences of protein-coding genes and nucleotide sequences of tRNA genes resolved some middle to deep branches among some teleostean fishes. The flounder mitochondrial genome does not show an indication of evolutionary rate difference among teleosts leading to difficulty in phylogenetic analyses, and our data is useful for future evolutionary studies dealing with higher teleostean fishes.     

The complete nucleotide sequence and gene organization of carp (Cyprinus carpio) mitochondrial genome

The complete sequence of the carp mitochondrial genome of 16,575 base pairs has been determined. The carp mitochondrial genome encodes the same set of genes (13 proteins, 2 rRNAs, and 22 tRNAs) as do other vertebrate mitochondrial DNAs. Comparison of this teleostean mitochondrial genome with those of other vertebrates reveals a similar gene order and compact genomic organization. The codon usage of proteins of carp mitochondrial genome is similar to that of other vertebrates. The phylogenetic relationship for mitochondrial protein genes is more apparent than that for the mitochondrial tRNA and rRNA genes.Correspondence to: F. Huang     

The complete mitochondrial DNA sequence of the shark Mustelus manazo: evaluating rooting contradictions to living bony vertebrates

A remarkable example of a misleading mitochondrial protein tree is presented, involving ray-finned fishes, coelacanths, lungfishes, and tetrapods, with sea lampreys as an outgroup. In previous molecular phylogenetic studies on the origin of tetrapods, ray-finned fishes have been assumed as an outgroup to the tetrapod/lungfish/coelacanth clade, an assumption supported by morphological evidence. Standard methods of molecular phylogenetics applied to the protein-encoding genes of mitochondria, however, give a bizarre tree in which lamprey groups with lungfish and, therefore, ray-finned fishes are not the outgroup to a tetrapod/lungfish/coelacanth clade. All of the dozens of published phylogenetic methods, including every possible modification to maximum likelihood known to us (such as inclusion of site heterogeneity and exclusion of potentially misleading hydrophobic amino acids), fail to place the ray-finned fishes in a biologically acceptable position. A likely cause of this failure may be the use of an inappropriate outgroup. Accordingly, we have determined the complete mitochondrial DNA sequence from the shark, Mustelus manazo, which we have used as an alternative and more proximal outgroup than the lamprey. Using sharks as the outgroup, lungfish appear to be the closest living relative of tetrapods, although the possibility of a lungfish/coelacanth clade being the sister group of tetrapods cannot be excluded.      

Origin of tetrapods inferred from their mitochondrial DNA affiliation to lungfish

Summary This paper shows that questions of an unexpected phylogenetic depth can be addressed by the study of mitochondrial DNA (mtDNA) sequences. For decades, it has been unclear whether coelacanth fishes or lungfishes are the closest living relatives of land vertebrates (Tetrapoda). Segments of mtDNA from a lungfish, the coelacanth, and a ray-finned fish were sequenced and compared to the published sequence of a frog mtDNA. A tree based on inferred amino acid replacements, silent transversions, and ribosomal RNA (rRNA) substitutions showed with statistical confidence that the lungfish mtDNA is more closely related to that of the frog than is the mtDNA of the coelacanth. This result appears to rule out the possibility that the coelacanth lineage gave rise to land vertebrates; hence, morphological characters that link the latter two groups are possibly due to convergent evolution or reversals and not to common descent. Besides supporting the theory that land vertebrates arose from an offshoot of the lineage leading to lungfishes, the molecular tree facilitates an evolutionary interpretation of the morphological differences among the living forms. It would appear that the common ancestor of lungfishes and tetrapods already possessed multiple morphological traits preadapting their locomotion, circulation, and respiration for life on land.     

Complete mitochondrial DNA sequence of Aulopus japonicus (Teleostei: Aulopiformes), a basal Eurypterygii: longer DNA sequences and higher-level relationships

For the first step toward resolution of the higher-level relationships of the order Aulopiformes (Teleostei: Eurypterygii) using longer DNA sequences, we determined the complete mitochondrial DNA sequence for Aulopus japonicus (Aulopodidae). The entire genome was purified by gene amplification using a long PCR technique, and the products were subsequently used as templates for PCR with 63 fish-versatile and 3 species-specific primers that amplify contiguous, overlapping segments of the entire genome. Direct sequencing of the PCR products demonstrated that the genome (16 653 base pairs [bp]) contained the same 37 mitochondrial genes (2 ribosomal RNA, 22 transfer RNA, and 13 protein-coding genes) as found in other vertebrates, with the gene order identical to that in typical vertebrates. Maximum-parsimony analysis using nucleotide sequences from the concatenated 12 protein-coding genes (no third codon positions and excluding the ND6 gene) plus 22 tRNA genes (stem regions only) from eight teleosts placed A. japonicus in a reasonable phylogenetic position; those from individual protein-coding genes and the concatenated 22 tRNA genes alone, however, did not reproduce the expected phylogeny with few exceptions, probably owing to insufficient phylogenetic information in these smaller data sets. This result suggests that further taxonomic sampling and sequencing efforts may clarify limits and intra- and interrelationships of this morphologically and ecologically diverse group of fishes using mitochondrial genomic (mitogenomic) data. Received: August 31, 2000 / Revised: December 20, 2000 / Accepted: January 23, 2001     

Organization of the Mitochondrial Genome of a Deep-Sea Fish, Gonostoma gracile (Teleostei: Stomiiformes): First Example of Transfer RNA Gene Rearrangements in Bony Fishes

We determined the complete nucleotide sequence of the mitochondrial genome (except for a portion of the putative control region) for a deep-sea fish, Gonostoma gracile. The entire mitochondrial genome was purified by gene amplification using long polymerase chain reaction (long PCR), and the products were subsequently used as templates for PCR with 30 sets of newly designed, fish-universal primers that amplify contiguous, overlapping segments of the entire genome. Direct sequencing of the PCR products showed that the genome contained the same 37 mitochondrial structural genes as found in other vertebrates (two ribosomal RNA, 22 transfer RNA, and 13 protein-coding genes), with the order of all rRNA and protein-coding genes, and 19 tRNA genes being identical to that in typical vertebrates. The gene order of the three tRNAs (tRNA^Glu, tRNA^Thr, and tRNA^Pro) relative to cytochrome b, however, differed from that determined in other vertebrates. Two steps of tandem duplication of gene regions, each followed by deletions of genes, can be invoked as mechanisms generating such rearrangements of tRNAs. This is the first example of tRNA gene rearrangements in a bony fish mitochondrial genome. Received August 5, 1998; accepted February 19, 1999.     

Gene and genome duplications in vertebrates: the one-to-four (-to-eight in fish) rule and the evolution of novel gene functions

One important mechanism for functional innovation during evolution is the duplication of genes and entire genomes. Evidence is accumulating that during the evolution of vertebrates from early deuterostome ancestors entire genomes were duplicated through two rounds of duplications (the 'one-to-two-to-four' rule). The first genome duplication in chordate evolution might predate the Cambrian explosion. The second genome duplication possibly dates back to the early Devonian. Recent data suggest that later in the Devonian, the fish genome was duplicated for a third time to produce up to eight copies of the original deuterostome genome. This last duplication took place after the two major radiations of jawed vertebrate life, the ray-finned fish (Actinopterygia) and the sarcopterygian lineage, diverged. Therefore the sarcopterygian fish, which includes the coelacanth, lungfish and all land vertebrates such as amphibians, reptiles, birds and mammals, tend to have only half the number of genes compared with actinopterygian fish. Although many duplicated genes turned into pseudogenes, or even 'junk' DNA, many others evolved new functions particularly during development. The increased genetic complexity of fish might reflect their evolutionary success and diversity.     

Complete mitochondrial genome of Trypauchen vagina (Perciformes, Gobioidei)

The complete mitochondrial genome of Trypauchen vagina was determined first. The genome is 16,686 bp in length and consists of 13 protein-coding genes, 22 tRNA genes, 2 ribosomal RNA genes, and 2 main non-coding regions [the control region (CR) and the origin of the light strand replication], the gene composition and order of which was similar to most other vertebrates. The overall base composition of T. vagina is T 27.6%, C 27.6%, A 29.5%, and G 15.3%, with a slight A+T bias of 57.1%. In addition to the discrete and conserved sequence blocks, an incomplete tandem repeat unit is detected within the CR. This mitogenome sequence data would play an important role in population genetics and phylogenetic analysis of the Gobioidei.     

Complete nucleotide sequence and gene rearrangement of the mitochondrial genome of the bell-ring frog, Buergeria buergeri (family Rhacophoridae)

In this study we determined the complete nucleotide sequence (19,959 bp) of the mitochondrial DNA of the rhacophorid frog Buergeria buergeri. The gene content, nucleotide composition, and codon usage of B. buergeri conformed to those of typical vertebrate patterns. However, due to an accumulation of lengthy repetitive sequences in the D-loop region, this species possesses the largest mitochondrial genome among all the vertebrates examined so far. Comparison of the gene organizations among amphibian species (Rana, Xenopus, salamanders and caecilians) revealed that the positioning of four tRNA genes and the ND5 gene in the mtDNA of B. buergeri diverged from the common vertebrate gene arrangement shared by Xenopus, salamanders and caecilians. The unique positions of the tRNA genes in B. buergeri are shared by ranid frogs, indicating that the rearrangements of the tRNA genes occurred in a common ancestral lineage of ranids and rhacophorids. On the other hand, the novel position of the ND5 gene seems to have arisen in a lineage leading to rhacophorids (and other closely related taxa) after ranid divergence. Phylogenetic analysis based on nucleotide sequence data of all mitochondrial genes also supported the gene rearrangement pathway.     

脊椎动物线粒体DNA的基因重排

将GenBank上已公布的321种脊椎动物mtDNA全序列,按纲整理归类,绘制基因排布图并进行比对。比对结果表明：81个物种的mtDNA中观察到基因重排现象,涉及脊椎动物各纲,其中9个物种同时存在基因顺序变化和基因倒置现象,所有的基因重排都涉及tRNA的变化。脊椎动物mtDNA基因顺序变化可分为3类：1)邻接的基因或片段的位置交换;2)接近于控制序列或轻链起始位点的基因或片段的位置变化,有时还伴随着控制序列的倍增;3)I-Q-M区域的变化。所有鸟类、蛇类、鳄类和有袋类的mtDNA具有各自独特的基因排列顺序。基因倒置现象常见于鱼类和哺乳类,且多表现为tRNA从轻链往重链上迁移。本文就这些基因重排现象、发生重排的机制和mtDNA基因重排在系统发生研究中的应用做一简要概述。     

Complete nucleotide sequence of the mitochondrial genome of Schlegel's tree frog Rhacophorus schlegelii (family Rhacophoridae): duplicated control regions and gene rearrangements

The complete nucleotide sequence (21,359 bp) of the mitochondrial DNA of the rhacophorid frog Rhacophorus schlegelii was determined. The gene content, nucleotide composition, and codon usage of this genome corresponded to those typical of vertebrates. However, the Rh. schlegelii genome was unusually large due to the inclusion of two control regions and the accumulation of lengthy repetitive sequences in these regions. The two control regions had 97% sequence similarity over 1,510 bp, suggesting the occurrence of concerted sequence evolution. Comparison of the gene organizations among anuran species revealed that the mitochondrial gene arrangement of Rh. schlegelii diverged from that of typical vertebrates but was similar to that of Buergeria buergeri. The positions of the tRNA-Leu(CUN) and tRNA-Thr genes were exchanged between Rh. schlegelii and B. buergeri. Based on parsimonious consideration and the basal phylogenetic position of B. buergeri, these genes seemed to have been rearranged in an ancestral lineage leading to Rh. schlegelii.     

Complete mitochondrial genome of Oxuderces dentatus (Perciformes, Gobioidei)

The complete mitochondrial genome (mitogenome) of Oxuderces dentatus was determined first. The genome was 17,116?bp in length and consisted of 13 protein-coding genes, 22 tRNA genes, 2 ribosomal RNA genes, and 2 main non-coding regions [the control region (CR) and the origin of the light strand replication], the gene composition and order of which was similar to most other vertebrates. The overall base composition of the heavy strand was T 27.9%, C 26.8%, A 30.2%, and G 15.1%, with a slight A+T bias of 58.1%. In addition to the discrete and conserved sequence blocks, unusual long tandem repeat unit (three 150-bp tandem repeat units and an incomplete copy of 146?bp) was also detected within CR. This mitogenome sequence data would play an important role in population genetics and phylogenetic analysis of the Gobioidei.     

缅甸陆龟线粒体全基因组的测序及分析

本文参照近缘物种的线粒体基因组序列,设计17对特异引物,采用LD-PCR、PCR及测序技术获得了我国广西产缅甸陆龟的线粒体全基因组序列,分析了其基因组特点和各基因的定位。结果表明:缅甸陆龟线粒体基因组全长为16813bp,碱基组成为35.30%A、26.47%T、12.09%G、26.14%C,包括13个蛋白质编码基因、2个rRNA基因、22个tRNA基因和1个非编码基因控制区(D-Loop区)。缅甸陆龟线粒体基因组各基因长度、位置与典型的脊椎动物相似,其编码蛋白质区域和rRNA基因与其它脊椎动物具有很高的同源性,显示龟类线粒体基因组在进化上十分保守。将缅甸陆龟的线粒体基因组序列提交到GenBank,获得的检索号为DQ656607。本文还结合GenBank中已发表的其它16种龟鳖类动物的线粒体基因组序列,探讨龟鳖类动物不同科间的系统进化关系。     

Molecular evidence on the origin of tetrapods and the relationships of the coelacanth

Coelacanths were believed to have gone extinct more than 80 million years ago - until the sensational rediscovery of one surviving member of this leneage, Latimeria chalumanae, in 1938. Since then, plaeontologists and comparative morphologists have argues whether coelacanths or lungfish (two groups of lobe-finned fish) are the living sistergroup of the third extant lineage, the tetrapods. Recent molecular phylogenetic data on this debate tend to favor the hypothesis that lungfish are the closest relatives of land vertebrates. Somewhat surprisingly, the strongest molecular support for this hypothesis stems from mitochondrial rather than nuclear DNA sequences, despite the expectation that the more-slowly evolving nuclear genes should be more appropriate in addressing a phylogenetic issue involving taxonomic groups that diverged around 400 million years ago. This molecular estimate might serve as a framework to test palepntological and physiological innovations and preadaptations that allowed Devanian lobe-finned fish to colonize land.