A multigene phylogeny examining evolutionary and ecological relationships in the Australo-papuan wrens of the subfamily Malurinae (Aves)

Nucleotide sequences from four mitochondrial genes and three nuclear introns were used to examine phylogenetic relationships within the Australo-papuan fairy-wrens (Passeriformes: Maluridae: Malurinae). A well-resolved and well-supported phylogenetic hypothesis of all species in the subfamily was generated. The tree contained three clades corresponding to groups with similar plumages previously identified in earlier studies: the "bi-color," "blue," and "chestnut-shouldered" groups. The genus Malurus was not monophyletic -Malurusgrayi formed a clade with two New Guinean genera Sipodotus and Clytomyias. We recommend M. grayi be reclassified into the genus Chenorhamphus Oustalet 1898. One other taxonomic change is recommended based on the large genetic distance between the two subspecies of Chenorhamphus grayi - the elevation of C. g.campbelli to specific status (= C. campbelli). Although the family Maluridae appears to have had its origins in Australia, the DNA data supports a New Guinean origin for the Malurini (Sipodotus, Clytomyias, Chenorhamphus, Malurus).     

Inferring the phylogeography and evolutionary history of the splendid fairy-wren Malurus splendens from mitochondrial DNA and spectrophotometry

The phylogeographic structure of the widely distributed arid and semi-arid Australian splendid fairy-wren Malurus splendens was investigated by using variation in plumage characters and mitochondrial DNA (mtDNA). We examined sequences of the mtDNA ND2 gene and used spectrophotometry to quantify chromatic variation in plumage in order to test the current morphology-based intraspecific taxonomy of M. splendens and to discriminate between hypotheses invoking allopatric and parapatric processes in the origin of diversity in the complex. Genetic diversity of M. splendens fell into three divergent geographically structured clades. One represents populations ascribed to the western subspecies M. s. splendens , the other populations of central M. s. musgravi and the third all eastern populations currently ascribed to M. s. emmottorum and M. s. melanotus . Plumage patterns clearly differentiate M. s. splendens and M. s. musgravi, and spectrophotometry identified a step-wise transition in spectra between M. s. melanotus and M. s. emmottorum . Congruence of patterns of phenotypic and genetic variation among western, central and eastern populations of M. splendens strongly suggests that these populations have diverged in allopatry on either side of historical biogeographic barriers in this region. Decoupled patterns of phenotypic and genetic diversity suggest that the divergence of M. s. melanotus and M. s. emmottorum may have occurred without periods of isolation perhaps in response to differences in local environmental conditions, or alternatively, mtDNA and plumage may have different rates of evolution. Critically, we encountered issues with the placement of the root of the M. splendens complex. The root was placed within the subspecies M. s. splendens separating its northern and southern populations and rendering the subspecies paraphyletic.     

Phylogenetic relationships of horned lizards (Phrynosoma) based on nuclear and mitochondrial data: evidence for a misleading mitochondrial gene tree

It has proven remarkably difficult to obtain a well-resolved and strongly supported phylogeny for horned lizards (Phrynosoma) because of incongruence between morphological and mitochondrial DNA sequence data. We infer the phylogenetic relationships among all 17 extant Phrynosoma species using >5.1 kb of mtDNA (12S rRNA, 16S rRNA, ND1, ND2, ND4, Cyt b, and associated tRNA genes), and >2.2kb from three nuclear genes (RAG-1, BDNF, and GAPD) for most taxa. We conduct separate and combined phylogenetic analyses of these data using maximum parsimony, maximum likelihood, and Bayesian methods. The phylogenetic relationships inferred from the mtDNA data are congruent with previous mtDNA analyses based on fewer characters and provide strong support for most branches. However, we detected strong incongruence between the mtDNA and nuclear data using comparisons of branch support and Shimodaira-Hasegawa tests, with the (P. platyrhinos+P. goodei) clade identified as the primary source of this conflict. Our analysis of a P. mcalliixP. goodei hybrid suggests that this incongruence is caused by reticulation via introgressive hybridization. Our preferred phylogeny based on an analysis of the combined data (excluding the introgressed mtDNA data) provides a new framework for interpreting character evolution and biogeography within Phrynosoma. In the context of this improved phylogeny we propose a phylogenetic taxonomy highlighting four clades: (1) Tapaja, containing the viviparous short-horned lizards P. ditmarsi, P. hernandesi, P. douglasii, and P. orbiculare; (2) Anota, containing species with prominent cranial horns (P. solare, P. mcallii, and the P. coronatum group); (3) Doliosaurus, containing three species lacking antipredator blood-squirting (P. modestum, P. platyrhinos, and P. goodei); and (4) Brevicauda, containing two viviparous species with extremely short tails that lack blood-squirting (P. braconnieri and P. taurus).     

Congruent Avian Phylogenies Inferred from Mitochondrial and Nuclear DNA Sequences

Recent molecular studies addressing the phylogenetic relationships of avian orders have had conflicting results. While studies using nuclear DNA sequences tend to support traditional taxonomic views, also supported by morphological data [(paleognaths (galloanseres (all other birds)))], with songbirds forming a clade within Neoaves (all other birds), analyses with complete mtDNA genomes have resulted in topologies that place songbirds as one of the earliest-diverging avian lineages. Considering that over half of the extant bird species are songbirds, these different results have very different implications for our understanding of avian evolution. We analyzed data sets comprising nearly 4 kb of mitochondrial DNA (mtDNA) (complete 12S, ND1, ND2, and cytochrome b) plus 600 bp of the nuclear gene c-mos for 15 birds that were chosen to represent all major avian clades and to minimize potential long-branch attraction problems; we used a partition-specific maximum likelihood approach. Our results show congruence with respect to the ingroup among phylogenies obtained with mtDNA and the nuclear gene c-mos, separately or combined. The data sets support a traditional avian taxonomy, with paleognaths (ratites and tinamous) occupying a basal position and with songbirds more derived and forming a monophyletic group. We also show that, for mtDNA studies, turtles may be a better outgroup for birds than crocodilians because of their slower rate of sequence evolution.     

Nuclear markers confirm taxonomic status and relationships among highly endangered and closely related right whale species

Right whales (genus: Eubalaena) are among the most endangered mammals, yet their taxonomy and phylogeny have been questioned. A phylogenetic hypothesis based on mitochondrial DNA (mtDNA) variation recently prompted a taxonomic revision, increasing the number of right whale species to three. We critically evaluated this hypothesis using sequence data from 13 nuclear DNA (nuDNA) loci as well as the mtDNA control region. Fixed diagnostic characters among the nuclear markers strongly support the hypothesis of three genetically distinct species, despite lack of any diagnostic morphological characters. A phylogenetics analysis of all data produced a strict consensus cladogram with strong support at nodes that define each right whale species as well as relationships among species. Results showed very little conflict among the individual partitions as well as congruence between the mtDNA and nuDNA datasets. These data clearly demonstrate the strength of using numerous independent genetic markers during a phylogenetics analysis of closely related species. In evaluating phylogenetic support contributed by individual loci, 11 of the 14 loci provided support for at least one of the nodes of interest to this study. Only a single marker (mtDNA control region) provided support at all four nodes. A study using any single nuclear marker would have failed to support the proposed phylogeny, and a strong phylogenetic hypothesis was only revealed by the simultaneous analysis of many nuclear loci. In addition, nu DNA and mtDNA data provided complementary levels of support at nodes of different evolutionary depth indicating that the combined use of mtDNA and nuDNA data is both practical and desirable.     

Subordinate superb fairy-wrens (Malurus cyaneus) parasitize the reproductive success of attractive dominant males

Explanations of cooperative breeding have largely focused on the indirect benefits philopatric offspring gain from investing in kin. However, recent molecular studies have revealed that in many species subordinates provision unrelated offspring. This has led to the re-evaluation of the direct and indirect benefits of helping behaviour. In this study, we used microsatellite genotyping to assess the extra-group reproductive success of subordinate superb fairy-wrens (Malurus cyaneus), a species with extremely high rates of extra-group paternity. Extra-group subordinate males sired 10.2% (193 out of 1895) of all offspring sampled between 1993 and 2000 and 21.4% (193 out of 901) of all illegitimate offspring sired by known males. The extra-group success of subordinates was greatly influenced by the attractiveness of their dominant male. Subordinates of attractive dominants sired more extra-group young than did average dominants. Evidence suggests that mate choice in superb fairy-wrens is error-prone and subordinates can gain direct reproductive benefits through parasitizing the reproductive success of attractive dominants.     

Molecular systematics of the western rattlesnake, Crotalus viridis (Viperidae), with comments on the utility of the D-loop in phylogenetic studies of snakes.

Crotalus viridis, the western rattlesnake, ranges throughout western North America and has been divided into at least eight subspecies. However, the validity of and relationships among these subspecies and the monophyly of C. viridis as a whole are questionable. We used mitochondrial DNA sequence data from the D-loop region and ND2 gene to examine the relationships among 26 populations of C. viridis and to test the monophyly of this species. These data were analyzed separately and combined using maximum-likelihood and maximum-parsimony. The C. viridis group was monophyletic in all combined analyses, consisting of two strongly divergent clades. We recommend that these clades be recognized as two distinct evolutionary species: C. viridis and C. oreganus. Crotalus viridis should be restricted to the subspecies viridis and nuntius and the remaining subspecies be assigned to the species C. oreganus. Our data do not allow strong evaluation of the validity of the subspecies. We found that the ND2 gene had greater sequence divergences among closely related individuals than the D-loop region, but this relationship reversed at higher levels of divergence. This pattern is apparently due to: (1) ND2 third positions evolving faster than the D-loop but becoming saturated at higher levels of divergence, and (2) the D-loop evolving faster than ND2 second (and possibly first) positions. Our results suggest that the ND2 gene is preferable for examining intraspecific relationships and the D-loop may better resolve relationships between species of snakes. The latter result is contrary to the common perception of the phylogenetic utility of the D-loop. Another unusual result is that the 145 bp spacer region, adjacent to the 5' end of the light strand of the D-loop, provides greater phylogenetic resolution than the 1030 bp D-loop.     

Seven genes of mitochondrial genome enabling differentiation of honeybee subspecies <Emphasis Type="Italic">Apis mellifera</Emphasis>

On the basis of comparative sequence analysis of 12 honeybee mitochondrial genes, seven genes enabling us to differentiate honeybees subspecies of the A, M, C, O evolutionary lineages were found. Applying comparative sequence analysis of ND2 gene mtDNA as an example on a statistically valid sample size, we showed a high level of differentiating ability of this gene and assumed that each of these seven genes probably can be used for differentiation of the subspecies within four evolutionary lineages.     

Mosaic genealogy of the Mus musculus genome revealed by 21 nuclear genes from its three subspecies

Patterns of genetic variation provide insight into the evolutionary history of a species. Mouse (Mus musculus) is a good model for this purpose. Here we present the analysis of genealogies of the 21 nuclear loci and one mitochondrial DNA region in M. musculus based on our nucleotide sequences of nine inbred strains from three M. musculus subspecies (musculus, domesticus, and castaneus) and one M. spicilegus strain as an outgroup. The mitochondrial DNA gene genealogy of those strains confirmed the introgression pattern of one musculus strain. When all the nuclear DNA data were concatenated to produce a phylogenetic tree of nine strains, musculus and domesticus strains formed monophyletic clusters with each other, while the two castaneus strains were paraphyletic. When each DNA region was treated independently, the phylogenetic networks revealed an unnegligibly high level of subspecies admixture and the mosaic nature of their genome. Estimation of ancestral and derived population sizes and migration rates suggests the effects of ancestral polymorphism and gene flow on the pattern of genetic variation of the current subspecies. Gene genealogies of Fut4 and Dfy loci also suggested existence of the gene flow between M. musculus and M. spicilegus or other distant species.     

The role of mitochondrial introgression in illuminating the evolutionary history of Nearctic treefrogs

Inferring the evolutionary history of lineages often becomes difficult when gene histories are in conflict with each other. Introgression, for example, can cause DNA sequences from one species to be more similar to sequences of a different species and lead to incongruence amongst gene trees. However, incorporating congruent and incongruent locus‐specific phylogenetic estimates with the geographical distribution of lineages may provide valuable insight into evolutionary processes important to speciation. In this study, we investigated mitochondrial introgression within the Hyla eximia group to better understand its role in illuminating the evolutionary history and phylogeography of these treefrogs. We reconstructed and compared the matrilineal history of the Hyla eximia group with estimates of evolutionary history inferred from nuclear genes. We tested for introgression within the mitochondrial and nuclear genes using a posterior predictive checking approach. Reconstructions of the species tree based on the mitochondrial DNA (mtDNA) and nuclear DNA data were strongly discordant. Introgression between lineages was widespread in the mtDNA data set (145 occurrences amongst 11 of the 16 lineages), but uncommon in the nuclear genes (12 occurrences amongst four of the 16 lineages). Nonetheless, the geographical structuring of mtDNA within species provides valuable information on biogeographical areas, ancient areas of hybridization, and unique histories of lineages within the H. eximia group. These results suggest that the combination of nuclear, mitochondrial, and spatial information can provide a more complete picture of ‘how evolutionary history played out’, particularly in cases where mitochondrial introgression is known to occur. © 2014 The Linnean Society of London     

Unexpected ceiling of genetic differentiation in the control region of the mitochondrial DNA between different subspecies of the ayu Plecoglossus altivelis

Sequence analyses of the non-coding, control region (CR) and coding region of the ND4-tRNA(Ser) genes in the mitochondrial DNA (mtDNA) were conducted for populations of the ayu Plecoglossus altivelis altivelis and the Ryukyu-ayu P. a. ryukyuensis. The level of genetic differentiation between the two subspecies evaluated from the CR data was substantially low, when comparing with that estimated from ND4-tRNA(Ser) gene region data, as well as those from nuclear genome data sets. By contrast, the differentiation between subspecies in the ND4-tRNA(Ser) gene region was substantial, being consistent with the results from the previous nuclear genome analyses. Results of UPGMA and minimum spanning network analyses also implied the unexpected ceiling of genetic differentiation in the CR. These results suggest that the CR does not reflect accurately the level of overall genetic differentiation between the populations of the ayu, but other coding regions of the mtDNA do reflect it so that the mtDNA on the whole may function as a rich source of useful markers for genetic assessment of populations of this species.     

Molecular phylogeny of hipposiderid bats (Chiroptera: Hipposideridae) from Solomon Islands and Cape York Peninsula,Australia

Throughout the Old World Tropics, examples of cryptic diversity have been demonstrated in leaf‐nosed bats from the Family Hipposideridae. In addition to cryptic diversity, the widespread distributions and graded morphologies of some species render the taxonomy of this family poorly resolved. We used sequences of the mitochondrial gene ND2 and the nuclear gene RAG1 to reconstruct molecular phylogenetic relationships for hipposiderid species. Specimens from Solomon Island and Cape York Peninsula, Australia, were sequenced and combined with published sequences from Southeast Asia. Our results suggest the presence of undescribed diversity in northern Australia. Sequences of ND2 and RAG1 for samples of Cape York Hipposideros ater were distinct from those of Southeast Asia, with corrected sequence divergence estimates for the mitochondrial gene exceeding 23%. In comparison, there was no cryptic diversity detected in Solomon Island specimens when compared to conspecifics from Southeast Asia. On the contrary, three species members of the diadema morphological group from the region exhibit variability in the mitochondrial gene ND2, far below that of other species included in the analyses.     

Genetic diversity of trout (genus Salmo) from its most eastern native range based on mitochondrial DNA and nuclear gene variation

Russia and western Asia harbour trout populations that have been classified as distinct species and subspecies, most often on the basis of morphological and ecological variation. In order to assess their origins and to verify whether traditional taxonomy reflects their evolutionary distinctiveness, we documented their genetic relationships on the basis of mitochondrial DNA (mtDNA) RFLP, mtDNA sequence analysis, and allozyme variation. Both mtDNA and nuclear gene variation defined two ancient phylogenetic assemblages of populations distributed among northern (Baltic, White, Barents), and southern (Black, Caspian, Aral) sea basins, between which gene flow has been possible but limited in postglacial times. These results supported the traditional taxonomic differentiation between populations of these two regions. They provided weak support for the taxonomic distinction of southern brown trout (Salmo trutta) populations based on their basin of origin. They also refuted the hypothesis that L. Sevan trout (Salmo ischchan) diverged from a primitive brown trout ancestor. Nevertheless, all trout populations from southern sea basins possessed private alleles or mtDNA genotypes and were genetically distinct Therefore, they represent unique gene pools that warrant individual recognition for conservation and management.     

Phylogeography of the Caribbean rock iguana (Cyclura): implications for conservation and insights on the biogeographic history of the West Indies

The Caribbean rock iguana, Cyclura, has had an unstable intrageneric taxonomy and an unclear phylogenetic position within the family Iguanidae. We use mtDNA sequence data to address these issues and explore the phylogeographic history of the genus. ND4 to leucine tRNA sequence data were collected from multiple individuals of each of the eight species of Cyclura (including 15 of 16 subspecies) and from four localities of Iguana iguana (representative of this species' broad geographic range). This data set was combined with sequence data from Sites et al. (1996, Mol. Biol. Evol. 13, 1087-1105) and analyzed under maximum-parsimony and maximum-likelihood optimization criteria. The ND4 region provided good resolution for the majority of nodes, as indicated by high bootstrap support. In agreement with several recent molecular studies, Cyclura is recovered as monophyletic and is not closely related to any other genus, whereas Iguana is strongly supported as the sister taxon to Sauromalus. This result is statistically more likely than other published hypotheses of Iguanid relationships. Cyclura shows a southeast to northwest speciation sequence in the Caribbean, with the most ancient lineage on the Puerto Rican Bank. The amount of interspecific sequence divergence within Cyclura (maximum 11.4%) is very high in comparison to data from other iguanid taxa at this locus, suggesting that this group either has been in the Caribbean for a very long time or has gone through a very rapid rate of evolution at this locus. Using dates from other published studies, we calculate a molecular clock that suggests that Cyclura colonized the Caribbean between 15 and 35 mya. Several questions regarding subspecific taxonomy are raised in the analysis and await further investigation using a more rapidly evolving marker such as nuclear microsatellites.     

Patterns of polymorphism and gene flow of gender-associated mitochondrial DNA lineages in European mussel populations

Mussels of the genus Mytilus have two types of mitochondrial DNA (mtDNA). The M type is transmitted paternally and the F type is transmitted maternally. RFLP analysis is used to assess phylogenetic relationships and nucleotide diversity and divergence for both mtDNA genomes in European populations of M. edulis and Atlantic and Mediterranean forms of M. galloprovincialis. Ten restriction endonucleases were used to assay variation in regions of the ND2 and COIII genes for a total of 77 individuals. F and M genomes show a concordant phylogenetic split into two major divergent clades, one specific to Mediterranean M. galloprovincialis and the other containing haplotypes from the three taxa. For both genomes, the geographical distribution of mtDNA variation suggests: (i) extensive levels of mtDNA introgression; (ii) asymmetric mtDNA gene flow from Atlantic to Mediterranean populations; and (iii) recurrent historical hybridization events. Significantly higher mtDNA diversity and divergence are observed for the M than F genome in all three Mytilus taxa, although the evolutionary forces responsible for these differences cannot be resolved. The extensive mtDNA gene flow between European Mytilus taxa conflicts with the restricted mtDNA introgression observed in American mussels , implying geographical variation in the nature of nuclear/mtDNA interactions regulating biparental inheritance.     

Mitochondrial phylogeny of the Chrysisignita (Hymenoptera: Chrysididae) species group based on simultaneous Bayesian alignment and phylogeny reconstruction

The ignita species group within the genus Chrysis includes over 100 cuckoo wasp species, which all lead a parasitic lifestyle and exhibit very similar morphology. The lack of robust, diagnostic morphological characters has hindered phylogenetic reconstructions and contributed to frequent misidentification and inconsistent interpretations of species in this group. Therefore, molecular phylogenetic analysis is the most suitable approach for resolving the phylogeny and taxonomy of this group. We present a well-resolved phylogeny of the Chrysis ignita species group based on mitochondrial sequence data from 41 ingroup and six outgroup taxa. Although our emphasis was on European taxa, we included samples from most of the distribution range of the C. ignita species group to test for monophyly. We used a continuous mitochondrial DNA sequence consisting of 16S rRNA, tRNA(Val), 12S rRNA and ND4. The location of the ND4 gene at the 3' end of this continuous sequence, following 12S rRNA, represents a novel mitochondrial gene arrangement for insects. Due to difficulties in aligning rRNA genes, two different Bayesian approaches were employed to reconstruct phylogeny: (1) using a reduced data matrix including only those positions that could be aligned with confidence; or (2) using the full sequence dataset while estimating alignment and phylogeny simultaneously. In addition maximum-parsimony and maximum-likelihood analyses were performed to test the robustness of the Bayesian approaches. Although all approaches yielded trees with similar topology, considerably more nodes were resolved with analyses using the full data matrix. Phylogenetic analysis supported the monophyly of the C. ignita species group and divided its species into well-supported clades. The resultant phylogeny was only partly in accordance with published subgroupings based on morphology. Our results suggest that several taxa currently treated as subspecies or names treated as synonyms may in fact constitute separate species. Our study provides a solid basis for further systematic investigations of this enigmatic insect group.     

Mitochondrial introgression and replacement between yellowhammers (Emberiza citrinella) and pine buntings (Emberiza leucocephalos) (Aves: Passeriformes)

In studies of phylogeography and taxonomy, strong emphasis is usually placed on the study of mitochondrial (mt)DNA. In the present study, we present a remarkable case in which highly phenotypically divergent species have almost no divergence in mtDNA. Yellowhammers ( Emberiza citrinella Linnaeus) and pine buntings ( Emberiza leucocephalos S. G. Gmelin) differ noticeably in appearance and song but hybridize in some areas of contact. They share a variety of closely-related mtDNA haplotypes, with little divergence in frequencies, indicating a mitochondrial divergence time sometime during or after the last major glacial period. By contrast, nuclear DNA (amplified fragment length polymorphism markers and CHD1Z gene sequences) differs more strongly between the species, and these differences can be used to identify intermediate genetic signatures of hybrids. The combined amount of mitochondrial diversity within yellowhammers and pine buntings is very low compared to other Emberiza species pairs, whereas the level of variation at the nuclear gene CHD1Z is comparable to that within other species pairs. Although it is difficult to completely reject the possibility that the two species split extremely recently and experienced rapid nuclear and phenotypic differentiation, we argue that the evidence better supports another possibility: the two species are older and mtDNA has recently introgressed between them, most likely as a result of a selective sweep. Mismatches between mitochondrial and nuclear phylogeographic patterns may occur more commonly than previously considered, and could have important implications for the fields of phylogeography and taxonomy.  © 2009 The Linnean Society of London, Biological Journal of the Linnean Society , 2009, 98 , 422–438.     

A comprehensive and validated molecular taxonomy of beaked whales, family Ziphiidae

DNA sequences from orthologous loci can provide universal characters for taxonomic identification. Molecular taxonomy is of particular value for groups in which distinctive morphological features are difficult to observe or compare. To assist in species identification for the little known family Ziphiidae (beaked whales), we compiled a reference database of mitochondrial DNA (mtDNA) control region (437 bp) and cytochrome b (384 bp) sequences for all 21 described species in this group. This mtDNA database is complemented by a nuclear database of actin intron sequences (925 bp) for 17 of the 21 species. All reference sequences were derived from specimens validated by diagnostic skeletal material or other documentation, and included four holotypes. Phylogenetic analyses of mtDNA sequences confirmed the genetic distinctiveness of all beaked whale species currently recognized. Both mitochondrial loci were well suited for species identification, with reference sequences for all known ziphiids forming robust species-specific clades in phylogenetic reconstructions. The majority of species were also distinguished by nuclear alleles. Phylogenetic comparison of sequence data from "test" specimens to these reference databases resulted in three major taxonomic discoveries involving animals previously misclassified from morphology. Based on our experience with this family and the order Cetacea as a whole, we suggest that a molecular taxonomy should consider the following components: comprehensiveness, validation, locus sensitivity, genetic distinctiveness and exclusivity, concordance, and universal accessibility and curation.     

Phylogenetic relationships between tuna species of the genus Thunnus (Scombridae: Teleostei): Inconsistent implications from morphology,nuclear and mitochondrial genomes

In order to infer phylogenetic relationships between tuna species of the genus Thunnus, partial sequences of the mitochondrial cytochrome b and ATPase genes were determined in all eight species. Supplemental restriction analysis on the nuclear rRNA gene was also carried out. Pacific northern bluefin tuna (Thunnus thynnus orientalis) was found to have mtDNA distinct from that of the Atlantic subspecies (T. t. thynnus) but very similar to that from the species albacore (T. alaluga). In contrast, no differentiation in nuclear genome was observed between the Atlantic and Pacific northern bluefin tunas. The Atlantic northern bluefin and southern bluefin tunas possessed mtDNA sequences very similar to species of yellowfin tuna group and not so similar to albacore and bigeye tunas which were morphologically assigned to the bluefin tuna group. The molecular data indicate that (1) mtDNA from albacore has been incorporated into the Pacific population of northern bluefin tuna and has extensively displaced the original mtDNA, and (2) albacore is the earliest offshoot, followed by bigeye tuna in this genus, which is inconsistent with the phylogenetic relationships between these tuna species inferred from morphology. Correspondence to: S. Chow     

Mitochondrial sequence diversity within a subspecies of savanna monkeys (Cercopithecus aethiops) is similar to that between subspecies

Cercopithecus aethiops can be classified into four subspecies by morphology and by geographic distribution. However, the phylogenetic relationship between these subspecies is unclear. We previously found five distinct haplogroups of mitochondrial DNA (mtDNA) in the subspecies C. aethiops aethiops at the restriction fragment length polymorphism (RFLP) level, and found that those haplogroups are parapatrically distributed in their habitat. To determine the relationship between subspeciation and haplogroup formation in a subspecies, we compared mtDNA control region and 12S rRNA gene sequences (approximately 700 bp) in C. a. aethiops, two other subspecies of C. aethiops, and two species of Cercopithecus: The diversity between haplogroups in C. a. aethiops was almost the same as that between subspecies. This similar level of diversification between and within haplogroups may explain why a previously obtained mtDNA tree did not show monophyletic branching according to subspecies.