Molecular phylogeny of the Chinese ranids inferred from nuclear and mitochondrial DNA sequences

The phylogeny of representative species of Chinese ranids was reconstructed using two nuclear (tyrosinase and rhodopsin) and two mitochondrial (12S rRNA, 16S rRNA) DNA fragments. Maximum parsimony, Bayesian, and maximum likelihood analyses were employed. In comparison with the results from nuclear and mitochondrial data, we used nuclear gene data as our preferred phylogenetic hypothesis. We proposed two families (Ranidae, Dicroglossidae) for Chinese ranids, with the exception of genus Ingerana. Within Dicroglossidae, four tribes were supported including Dicroglossini, Paini, Limnonectini, and Occidozygini. A broader sampling strategy and evidence from additional molecular markers are required to decisively evaluate the evolutionary history of Chinese ranids.     

A phylogeny of Chinese species in the genus Phrynocephalus (Agamidae) inferred from mitochondrial DNA sequences

We investigated the phylogenetic relationships among most Chinese species of lizards in the genus Phrynocephalus (118 individuals collected from 56 populations of 14 well-defined species and several unidentified specimens) using four mitochondrial gene fragments (12S rRNA, 16S rRNA, cytochrome b, and ND4-tRNA(LEU)). The partition-homogeneity tests indicated that the combined dataset was homogeneous, and maximum-parsimony (MP), neighbor-joining (NJ), maximum-likelihood (ML) and Bayesian (BI) analyses were performed on this combined dataset (49 haplotypes including outgroups for 2058bp in total). The maximum-parsimony analysis resulted in 24 equally parsimonious trees, and their strict consensus tree shows that there are two major clades representing the Chinese Phrynocephalus species: the viviparous group (Clade A) and the oviparous group (Clade B). The trees derived from Bayesian, ML, and NJ analyses were topologically identical to the MP analysis except for the position of P. mystaceus. All analyses left the nodes for the oviparous group, the most basal clade within the oviparous group, and P. mystaceus unresolved. The phylogenies further suggest that the monophyly of the viviparous species may have resulted from vicariance, while recent dispersal may have been important in generating the pattern of variation among the oviparous species.     

Molecular phylogeny of the speciose vole genus Microtus (Arvicolinae, Rodentia) inferred from mitochondrial DNA sequences

Voles of the genus Microtus represent one of the most speciose mammalian genera in the Holarctic. We established a molecular phylogeny for Microtus to resolve contentious issues of systematic relationships and evolutionary history in this genus. A total of 81 specimens representing ten Microtus species endemic to Europe as well as eight Eurasian, six Asian and one Holarctic species were sequenced for the entire cytochrome b gene (1140 bp). A further 25 sequences were retrieved from GenBank, providing data on an additional 23, mainly Nearctic, Microtus species. Phylogenetic analysis of these 48 species generated four well-supported monophyletic lineages. The genus Chionomys, snow voles, formed a distinct and well-supported lineage separate from the genus Microtus. The subgenus Microtus formed the strongest supported lineage with two sublineages displaying a close relationship between the arvalis species group (common voles) and the socialis species group (social voles). Monophyly of the Palearctic pitymyid voles, subgenus Terricola, was supported, and this subgenus was also subdivided into two monophyletic species groups. Together, these groupings clarify long-standing taxonomic uncertainties in Microtus. In addition, the "Asian" and the Nearctic lineages reported previously were identified although the latter group was not supported. However, relationships among the main Microtus branches were not resolved, suggesting a rapid and potentially simultaneous radiation of a widespread ancestor early in the history of the genus. This and subsequent radiations discernible in the cytochrome b phylogeny, show the considerable potential of Microtus for analysis of historical and ecological determinants of speciation in small mammals. It is evident that speciation is an ongoing process in the genus and that the molecular data provides a vital insight into current species limits as well as cladogenic events of the past.     

Molecular phylogeny of the subfamily Schizothoracinae (Teleostei: Cypriniformes: Cyprinidae) inferred from complete mitochondrial genomes

The schizothoracine fishes, members of the Teleost order Cypriniformes, are one of the most diverse group of cyprinids in the Qinghai–Tibetan Plateau and surrounding regions. However, taxonomy and phylogeny of these species remain unclear. In this study, we determined the complete mitochondrial genome of Schizopygopsis malacanthus. We also used the newly obtained sequence, together with 31 published schizothoracine mitochondrial genomes that represent eight schizothoracine genera and six outgroup taxa to reconstruct the phylogenetic relationships of the subfamily Schizothoracinae by different partitioned maximum likelihood and partitioned Bayesian inference at nucleotide and amino acid levels. The schizothoracine fishes sampled form a strongly supported monophyletic group that is the sister taxon to Barbus barbus. A sister group relationship between the primitive schizothoracine group and the specialized schizothoracine group + the highly specialized schizothoracine group was supported. Moreover, members of the specialized schizothoracine group and the genera Schizothorax, Schizopygopsis, and Gymnocypris were found to be paraphyletic.     

Molecular phylogeny of the family Dicroglossidae (Amphibia: Anura) inferred from complete mitochondrial genomes

The fork-tongued frogs, members of the amphibian Order Anura, belong to the family Dicroglossidae and are one of the most diverse groups of Anuran frogs; however, their taxonomy and phylogeny remain controversial. In the present study, sixteen dicroglossine mitochondrial genomes representing nine dicroglossine genera and 23 other neobatrachian taxa, were used to reconstruct the phylogenetic relationships of the family Dicroglossidae using different partitioned maximum likelihood and partitioned Bayesian inference methods at both the nucleotide and amino acid levels. The sampled fork-tongued frogs form a strongly supported monophyletic group that is the sister taxon to another well-supported clade that includes representatives of the families Ranidae, Rhacophoridae, and Mantellidae. The monophyly of the subfamily Occidozyginae and Dicroglossinae was revealed with strong supports, and two major clades were supported within Dicroglossinae. The sister-group relationship between the genera Limnonectes and the tribe Paini was supported. In addition, a sister-group relationships between Fejervarya and Euphlyctis + Hoplobatrachus, between Quasipaa and Yerana, and between Feirana and Nanorana are well supported. Estimates of divergence times revealed the divergence of Dicroglossidae during the Late Upper Cretaceous to the Early Eocene, and diversification of the major dicroglossine genera from the Early Eocene to the Middle Miocene.     

Molecular phylogeny and systematics of the Barbinae (Teleostei: Cyprinidae) in China inferred from mitochondrial DNA sequences

The taxonomy and phylogeny of the Chinese species of the Barbinae (Cypriniformes) has a confusing history. In this study, partial sequences of four mitochondrial genes (cyt b, COI, ND4 and 16S rRNA) from 75 Barbinae species and 38 outgroup species were used to investigate the taxonomy and phylogeny within the Barbinae in China. The monophyly of Neolissochilus, Sikukia and Tor are not supported. Neolissochilus benasi might represent a new genus, and Tor hemispinus and Tor qiaojiensis should be moved into Neolissochilus. Sikukia flavicaudata is not Sikukia species. Puntius paucimaculatus might be a synonym of Puntius semifasciolatus. Puntius semifasciolatus does not belong to Puntius. Onychostoma barbatum might consist of more than one species. Our molecular results corroborate that Acrossocheilus stenotaeniatus is a synonym of Acrossocheilus longipinnis. Finally, Barbonymus gonionotus from Menglun, Yunnan should be Poropuntius huangchuchieni.     

DNA barcoding of genus Metapenaeopsis (Decapoda: Penaeidae) and molecular phylogeny inferred from mitochondrial and nuclear DNA sequences

Metapenaeopsis Bouvier, 1905 is the most diverse genus within Penaeidae. Metapenaeopsis shrimps exhibited subtle morphological differences, which make identification a difficult task based on taxonomic keys alone. In this study, we carried out DNA barcoding and phylogenetic analyses to examine taxonomy and phylogeny of genus Metapenaeopsis based on mitochondrial (COI) and nuclear (PEPCK and NaK) genes. Despite limited performance of DNA barcoding in delineating Metapenaeopsis shrimps, it questioned the taxonomic status of the two subspecies, Metapenaeopsis mogiensis intermedia and Metapenaeopsis mogiensis mogiensis, as well as three separate species: Metapenaeopsis provocatoria longirostris, Metapenaeopsis quinquedentata and Metapenaeopsis velutina. The major pattern of relationships between all studied taxa of Metapenaeopsis was similar across all analytical methods in which species with one-valved petasma were genetically distinct from those with two-valved petasma. As expected from morphology, the remaining species with stridulating organ constituted a strongly supported clade. In contrast, a paraphyletic clade was resolved for species without stridulating organ which contradicts Crosnier's morphological classification scheme for Metapenaeopsis. Overall, the present molecular data indicated that the shape of petasma and stridulating organ were both phylogenetically significant morphological characters for this genus, adding further evidence for the Crosnier's proposal.     

Molecular phylogeny of Moenkhausia (Characidae) inferred from mitochondrial and nuclear DNA evidence

Moenkhausia is one of the most speciose genera in Characidae, currently composed of 75 nominal species of small fishes distributed across South American hydrographic basins, primarily the Amazon and Guyanas. Despite the large number of described species, studies involving a substantial number of its species designed to better understand their relationships and putative monophyly are still lacking. In this study, we analysed a large number of species of Moenkhausia to test the monophyly of the genus based on the phylogenetic analysis of DNA sequences of two mitochondrial and three nuclear genes. The in‐group included 29 species of Moenkhausia, and the out‐group was composed of representatives of Characidae and other members of Characiformes. All species of Moenkhausia belong to the same clade (Clade C); however, they appear distributed in five monophyletic groups along with other different genera, which means that Moenkhausia is polyphyletic and indicates the necessity of an extensive revision of the group.     

Molecular phylogeny of Sinocyclocheilus (Cypriniformes: Cyprinidae) inferred from mitochondrial DNA sequences

More than 10 species within the freshwater fish genus Sinoncyclocheilus adapt to caves and show different degrees of degeneration of eyes and pigmentation. Therefore, this genus can be useful for studying evolutionary developmental mechanisms, role of natural selection and adaptation in cave animals. To better understand these processes, it is indispensable to have background knowledge about phylogenetic relationships of surface and cave species within this genus. To investigate phylogenetic relationships among species within this genus, we determined nucleotide sequences of complete mitochondrial cytochrome b gene (1140 bp) and partial ND4 gene (1032 bp) of 31 recognized ingroup species and one outgroup species Barbodes laticeps. Phylogenetic trees were reconstructed using maximum parsimony, Bayesian, and maximum likelihood analyses. Our phylogenetic results showed that all species except for two surface species S. jii and S. macrolepis clustered as five major monophyletic clades (I, II, III, IV, and V) with strong supports. S. jii was the most basal species in all analyses, but the position of S. macrolepis was not resolved. The cave species were polyphyletic and occurred in these five major clades. Our results indicate that adaptation to cave environments has occurred multiple times during the evolutionary history of Sinocyclocheilus. The branching orders among the clades I, II, III, and IV were not resolved, and this might be due to early rapid radiation in Sinocyclocheilus. All species distributed in Yunnan except for S. rhinocerous and S. hyalinus formed a strongly supported monophyletic group (clade V), probably reflecting their common origins. This result suggested that the diversification of Sinocyclocheilus in Yunnan may correlate with the uplifting of Yunnan Plateau.     

Phylogenetic estimation of Mytilidae in the East China Sea inferred from mitochondrial genes and nuclear DNA sequence variation

We performed a phylogenetic estimation of the family Mytilidae in the East China Sea based on nuclear internal transcribed spacer (ITS) genes and two mitochondrial genes (COI and 16S RNA). Analysis of five mytilid species based on each of the three genes resulted in mostly congruent trees, although there were some discrepancies in the classification of these species. We combine the results obtained from the three separate analyses to provide a phylogenetic estimation of Mytilidae. We found that the Mytilidae was divided into two major lineages: in one clade, Mytilus galloprovincialis was grouped with Mytilus coruscus; in the second clade, Septifer bilocularis was placed at the basal position in an individual clade, and Perna viridis and Musculista senhousia were recovered as a monophyletic group. Although these finding provide important insights into the taxonomic relationships among the Mytilidae, many aspects of Mytilidae phylogeny remain unresolved. Further analysis based on more molecular information and extensive taxon sampling is necessary to elucidate the phylogenetic relationships among the major lineages within the Mytilidae.     

Molecular phylogeny of Clupeiformes (Actinopterygii) inferred from nuclear and mitochondrial DNA sequences

The taxonomy of clupeiforms has been extensively studied, yet phylogenetic relationships among component taxa remain controversial or unresolved. Here we test current and new hypotheses of relationships among clupeiforms using mitochondrial rRNA genes (12S and 16S) and nuclear RAG1 and RAG2 sequences (total of 4749bp) for 37 clupeiform taxa representing all five extant families and all subfamilies of Clupeiformes, except Pristigasterinae, plus seven outgroups. Our results, based on maximum parsimony, maximum likelihood, and Bayesian analyses of these data, show that some traditional hypotheses are supported. These include the monophyly of the families Engraulidae, consisting of two monophyletic subfamilies, Engraulinae (Engraulis and Anchoa) and Coilinae (Coilia and Setipinna), and Pristigasteridae (here represented only by Ilisha and Pellona). The basal position of Denticeps among clupeiforms is consistent with the molecular data when base compositional biases are accounted for. However, the monophyly of Clupeidae was not supported. Some clupeids were more closely related to taxa assigned to Pristigasteridae and Chirocentridae (Chirocentrus). These results suggest that a major revision in the classification of clupeiform fishes may be necessary, but should await a more complete taxonomic sampling and additional data.     

从细胞色素b基因序列探讨笛鲷属的分子系统发生关系

测定了9种中国南海的笛鲷属鱼类的细胞色素b基因的部分序列,结合来自GenBank中1种分布于菲律宾和9种分布于美国大西洋的笛鲷属鱼类的相应同源序列,用邻接法和最大简约法构建分子系统树。结果显示:红鳍笛鲷(Lutjanuserythropterus)与红笛鲷(L.sanguineus)之间的同源序列碱基差异百分率只有0.32%,支持二者是同种异名的观点;中国南海的笛鲷属鱼类间的平均碱基差异要高于美国大西洋笛鲷属鱼类。在MP和NJ树中,美国大西洋笛鲷表现为亲缘关系较近,来源于中国南海的笛鲷鱼类相对集中在树的基部,分歧较大。这与所研究的笛鲷地理分布和地理隔离基本相一致,同时也说明中国南海笛鲷分化较早并且分歧较大。     

Tracing plant Mitochondrial DNA evolution: rearrangements of the ancient mitochondrial gene cluster trnA-trnT-nad7 in liverwort phylogeny

Whereas frequent recombination characterizes flowering plant mitochondrial genomes, some mitochondrial gene arrangements may, in contrast, be conserved between streptophyte algae and early land plant clades (bryophytes). Here we explore the evolutionary fate of the mitochondrial gene arrangement trnA-trnT-nad7, which is conserved among the alga Chara, the moss Physcomitrella, and the liverwort Marchantia, although trnT is inverted in orientation in the latter. Surprisingly, we now find that the Chara-type gene arrangement is generally conserved in mosses, but that trnT is lacking between trnA and nad7 in all simple-thalloid and leafy (jungermanniid) liverworts. The ancient gene continuity trnA-trnT-nad7 is, however, conserved in Blasia, representing the sister lineage to all other complex-thalloid (marchantiid) liverworts. The recombinogenic insertion of short sequence stretches, including nad5 and rps7 pseudogene fragments copied from elsewhere in the liverwort mtDNA, likely mediated a subsequent inversion of trnT and flanking sequences in a basal grade of marchantiid liverworts, which was then followed by an independent secondary loss of trnT in derived marchantiid taxa later in evolution. In contrast to the previously observed extreme degree of coding sequence conservation and the assumed absence of active recombination in Marchantia mtDNA, this now reveals a surprisingly dynamic evolution of marchantiid liverwort mitochondrial genomes.     

Phylogenetic relationships of Nembrothinae (Mollusca: Doridacea: Polyceridae) inferred from morphology and mitochondrial DNA

Within the Polyceridae, Nembrothinae includes some of the most striking and conspicuous sea slugs known, although several features of their biology and phylogenetic relationships remain unknown. This paper reports a phylogenetic analysis based on partial sequences of two mitochondrial genes (cytochrome c oxidase subunit I and 16S rRNA) and morphology for most species included in Nembrothinae. Our phylogenetic reconstructions using both molecular and combined morphological and molecular data support the taxonomic splitting of Nembrothinae into several taxa. Excluding one species (Tambja tentaculata), the monophyly of Roboastra was supported by all the phylogenetic analyses of the combined molecular data. Nembrotha was monophyletic both in the morphological and molecular analyses, always with high support. However, Tambja was recovered as para- or polyphyletic, depending on the analysis performed. Our study also rejects the monophyly of "phanerobranch" dorids based on molecular data.     

Phylogenetic relationships among Pneumocystis from Asian macaques inferred from mitochondrial rRNA sequences

The presence of Pneumocystis organisms was detected by nested-PCR at mitochondrial large subunit (mtLSU) rRNA gene in 23 respiratory samples from Asian macaques representing two species: Macaca mulatta and M. fascicularis. A very high level of sequence heterogeneity was detected with 18 original sequence types. Two genetic groups of Pneumocystis could be distinguished from the samples. Within each group, the extent of genetic divergence was low (2.5+/-1.4% in group 1 and 2.3+/-1.7% in group 2). Genetic divergences were systematically higher when macaque-derived sequence types were compared with Pneumocystis mtLSU sequences from other primate species (from 5.3+/-2.7% to 19.3+/-3.0%). The two macaque-derived groups may be considered as distinct Pneumocystis species. Surprisingly, these Pneumocystis species were recovered from both M. mulatta and M. fascicularis suggesting that host-species restriction may not systematically occur in the genus Pneumocystis. Alternatively, these observations question about the species concept in macaques.     

Molecular systematics of theDrosophila hydei subgroup as inferred from mitochondrial DNA sequences

The phylogeny of theDrosophila hydei subgroup, which is a member of theD. repleta species group, was inferred from 1,515 base pairs of mitochondrial DNA sequence of the cytochrome oxidase subunits I, II, and III. Four of the seven species in the subgroup were examined, which are placed into two taxonomic complexes: theD. bifurca complex (D. bifurca) andD. nigrohydei) and theD. hydei complex (D. hydei and (D. eohydei). Both complexes appear to be monophyletic, although theD. bifurca complex is only weakly supported. The evolution of chromosomal change, interspecific crossability, sperm gigantism, and divergence times of the subgroup is discussed in a phylogenetic context. Correspondence to: G. Spicer     

Molecular phylogeny of mangroves VIII: Analysis of mitochondrial DNA variation for species identification and relationships in Indian mangrove Rhizophoraceae

Ten species belonging to four genera of the mangrove tribe Rhizophoreaefound in the Indian subcontinent were analysed for species identification andgenetic relationship using nine mitochondrial gene probes. RFLP patternobservedwith 27 probe enzyme combinations the genera Rhizophora,Bruguiera, Ceriops andKandelia differentiated these species into three classesofmitotypes with further resolution within them. Clustering of these mitotypesindicated that Rhizophora was more closely related toCeriops-Kandelia than to theBruguiera. Though the component species of each genusclustered together, a high degree of heterogeneity was observed among fourspecies of the genus Rhizophora and three species of genusBruguiera. The variation between two species ofCeriops was minimal. Species-specific profiles wereobserved for all the species in some probe-enzyme combination. Though themonotypic genus Kandelia shared a number of loci withgenusCeriops, it remained distinct. The putative parents of thenaturally occuring interspecific hybrid in Pichavaram were reconfirmed to beR. apiculata and R. mucronata. Theresults are discussed with regard to the taxonomic and phylogeneticrelationships between different species and genera of the tribe Rhizophoreae.     

Molecular analysis for mitochondrial DNA disorders

In this article, we review the current methodologies used for the molecular diagnosis of mitochondrial DNA defects. Definition of mitochondrial disorders at the molecular level has been difficult because of both clinical and genetic heterogeneity. Direct DNA analysis for common point mutations and large mtDNA deletions is readily performed and can be done routinely. However, a large number of patients who have the clinical manifestations and muscle pathology findings consistent with mitochondrial DNA disorders do not have detectable common mutations. Additional mutation screening methods are required for the detection of rare and previously undescribed mutations in the mitochondrial genome.     

Molecular analysis of the mitochondrial genome of Helianthus annuus in relation to cytoplasmic male sterility and phylogeny

Summary A circular supercoiled mitochondrial DNA plasmid P₁ (1.45 kb) is shown in both normal fertile plants of Helianthus annuus, and some cytoplasmic male sterile lines (CMS A and CMS P). In contrast, no plasmid is found in some other types of CMS C, I, B and K. A circular supercoiled DNA (P₂) of higher molecular weight (1.8 kb) is observed in CMS F. The mitochondrial plasmid P₁ was cloned, nick-translated and hybridized with native mitochondrial DNA from different lines of male fertile, CMS or wild Helianthus. No sequence homology has been detected between plasmid DNA P₁ and high molecular weight mitochondrial DNA in any line examined. A slight hybridization occurs between plasmids P₁ and P₂. Thus, there is no apparent relationship between mitochondrial plasmid DNA and CMS or Helianthus species. On the contrary, each Helianthus CMS and male fertile strain can be characterized by digestion fragment patterns (Sal I and Bgl I). Analysis of mitochondrial DNA from wild Helianthus strains indicated a relation between some CMS and the strain from which they were maternally derived, as for example CMS I and H. annuus ssp lenticularis and CMS F and H. petiolaris fallax. On the basis of restriction endonuclease patterns, a CMS phylogenic tree is proposed which illustrates a molecular polymorphism in the mitochondrial genome of Helianthus.     

Molecular phylogeny and biogeography of woolly flying squirrel (Rodentia: Sciuridae), inferred from mitochondrial cytochrome b gene sequences

To investigate the genetic diversity between the populations of woolly flying squirrels (Eupetaurus) from the eastern and western extremes of the Himalayas, partial mitochondrial cytochrome b gene sequences (390-810 bp) that were determined from the museum specimens were analyzed using maximum parsimony (MP) and maximum likelihood (ML) methods. The molecular data reveal that the two specimens that were collected in northwestern Yunnan (China) are members of the genus Eupetaurus. Reconstructed phylogenetic relationships show that the populations of Eupetaurus in the eastern and western extremes of the Himalayas are two distinct species with significant genetic differences (12%) and diverged about 10.8 million years ago. Eupetaurus is significantly different from Petaurista and Pteromys. The level of estimated pairwise-sequence divergence observed between Eupetaurus and Petaurista or Pteromys is greater than that observed between Eupetaurus and Trogopterus, Belomys, Glaucomys, or Hylopetes. Considering the divergence time of the two Eupetaurus groups, the glaciations and the uplift of the Himalayas and Qinghai-Tibet plateau during the Pliocene-Pleistocene period might be the major factors affecting the present distribution of Eupetaurus along the Himalayas.