The Emergence of an Endangered Species: Evolution and Phylogeny of the <Emphasis Type="Italic">Trachypithecus geei</Emphasis> of Bhutan

Golden langurs (Trachypithecus geei) are an endangered primate species in Bhutan. We discuss their evolution in terms of phylogeny, ecology, and biogeography. We test the hypothesis that rivers and mountains in Bhutan isolated a population of capped langurs (Trachypithecus pileatus) that later speciated into the morphologically distinct T. geei. Trachypithecus, the genus to which both capped and golden langurs belong, spread north from a paleorefuge in south China, and Semnopithecus (gray langurs) spread east and northward from a refuge in south India. We show that the 2 genera both arrived in Bhutan and were separated from each other by the Sunkosh River and Black Mountains. Likewise, a population of capped langurs isolated from parental populations by rivers speciated into the distinct golden langurs. We conducted field surveys covering the entire range of langurs in Bhutan. The Sunkosh River and Black Mountain range in west Bhutan isolate gray langurs and golden langurs from each other. In the east, the Manas River system (Manas-Mangde) served as a barrier between golden and capped langurs. However, it is an imperfect barrier and a contact zone between the 2 species occurred on the banks of the Mangde River. Second, we reconstructed the evolutionary history of the langurs of Bhutan via molecular phylogenetic tools. We sequenced the cytochrome b region (cyt b) of the mitochondrial DNA (mtDNA) to model a phylogeny. It revealed the distinct evolutionary paths of the golden, capped, and gray langurs. As predicted, golden and capped langurs are closely related to each other and to other species in Trachypithecus from Southeast Asia. The gray langur of Bhutan grouped into a distinct clade with conspecifics in Semnopithecus from India and Nepal. The south Indian clade of gray langurs is more ancient, with the Bhutan and Nepal gray langurs having diverged later, which fits with the glacial models of ice sheet retreats and colonization of South Asia by gray langurs from south India north toward the Himalayas. Likewise, the golden and capped langur clade are the most derived and divergent from the older groups of Trachypithecus in Southeast Asia, which also fits with paleorefuge models of recolonization by Trachypithecus into the rest of Southeast Asia and north toward the Himalayas from paleorefuges in Southeast Asia. As predicted, golden and capped langurs are closely related to each other and gray langurs are only distantly related to them. The divergence between capped and golden langurs is more recent, while the split between Trachypithecus and Semnopithecus is more ancient and took place before the Pliocene.     

Molecular analyses of mitochondrial pseudogenes within the nuclear genome of arvicoline rodents

Nuclear sequences of mitochondrial origin (numts) are common among animals and plants. The mechanism(s) by which numts transfer from the mitochondrion to the nucleus is uncertain, but their insertions may be mediated in part by chromosomal repair mechanisms. If so, then lineages where chromosomal rearrangements are common should be good models for the study of numt evolution. Arvicoline rodents are known for their karyotypic plasticity and numt pseudogenes have been discovered in this group. Here, we characterize a 4 kb numt pseudogene in the arvicoline vole Microtus rossiaemeridionalis. This sequence is among the largest numts described for a mammal lacking a completely sequenced genome. It encompasses three protein-coding and six tRNA pseudogenes that span ∼25% of the entire mammalian mitochondrial genome. It is bordered by a dinucleotide microsatellite repeat and contains four transposable elements within its sequence and flanking regions. To determine the phylogenetic distribution of this numt among the arvicolines, we characterized one of the mitochondrial pseudogenes (cytochrome b) in 21 additional arvicoline species. Average rates of nucleotide substitution in this arvicoline pseudogene are estimated as 2.3 × 10⁻⁸ substitutions/per site/per year. Furthermore, we performed comparative analyses among all species to estimate the age of this mitochondrial transfer at nearly 4 MYA, predating the origin of most arvicolines. All sequences generated in this study have been deposited within the GenBank database.     

Molecular systematics and conservation of the langurs and leaf monkeys of South Asia

Numerous morphology-based classification schemes have been proposed for langurs and leaf monkeys of South Asia but there is very little agreement between them. An incorrect classification scheme when used as a basis for biogeographic studies can support erroneous hypotheses. Further, lack of taxonomic resolution will also confound conservation efforts, given that conservation biologists use traditional morphology-based-classification schemes to prioritize species for conservation. Here, I have revisited recent molecular phylogenetic studies done on langurs and leaf monkeys of South Asia. Results from these studies are in turn used to derive a rational and scientific basis for prioritizing species for conservation. Molecular data support the classification of langurs of the Indian subcontinent—Hanuman, Nilgiri and purple-faced langurs—in the genus Semnopithecus, whereas Phayre’s leaf monkey along with other Southeast Asian leaf monkeys form another distinct clade (Trachypithecus). The phylogenetic position of capped and golden langurs remains unresolved. Molecular data suggest that they are closely related to each other but this group might have evolved through past hybridization between Semnopithecus and Trachypithecus. Additionally, genetic data also support the splitting of the so-called Hanuman langurs into at least three species. The scores for taxonomic uniqueness of langurs and leaf monkeys of South Asia were revised using this molecular phylogeny-based classification. According to the revised scores, Phayres leaf monkey and golden langur are priority species for conservation followed by capped and Nilgiri langurs.     

Three genetically divergent lineages of the Oryx in eastern Africa: Evidence for an ancient introgressive hybridization

Phylogeographic and population genetic studies using sequence information are frequently used to infer species boundaries and history; and to assess hybridization and population level processes. In this study, partial mitochondrial DNA (mtDNA) control region (423 bp) and cytochrome b sequences (666 bp) of Oryx beisa sampled from five isolated localities in its entire current range in Africa were analyzed to investigate the extent of genetic variation and differentiation between populations. We observed high nucleotide diversity at the control region in the total sample (6.3%) but within populations, it varied considerably ranging from 1.6% to 8.1%. Population pairwise genetic differentiation was generally significantly high (ranging from F _ST = 0.15, P<0.01 to F _ST = 0.54, P<0.001). In the total sample, 29 and 12 haplotypes were observed in the control region and the cytochrome b data sets respectively. For both data sets, the haplotypes cluster into three distinct clades (sequence divergence ranged from 6.0%–12.9% to 0.8%–1.0% for the control region and cytochrome b sequences, respectively) that do not correspond to sampling locations. Two of these clades are found in the same localities (Samburu and Marsabit), which represent the O.beisa beisa subspecies, whereas the last clade represents the fringe-eared oryx (O. beisa callotis). We interpret these findings in terms of an ancient hybridization and introgression between two formerly isolated taxa of Oryx beisa.     

Phylogenetic position of the langur genera <Emphasis Type="Italic">Semnopithecus</Emphasis> and <Emphasis Type="Italic">Trachypithecus</Emphasis> among Asian colobines,and genus affiliations of their species groups

Background  

The evolutionary history of the Asian colobines is less understood. Although monophyly of the odd-nosed monkeys was recently confirmed, the relationships among the langur genera Presbytis, Semnopithecus and Trachypithecus and their position among Asian colobines remained unclear. Moreover, in Trachypithecus various species groups are recognized, but their affiliations are still disputed. To address these issues, mitochondrial and Y chromosomal sequence data were phylogenetically related and combined with presence/absence analyses of retroposon integrations.     

Phylogenetic position of the monotypic Des Murs’ Wiretail ( Sylviorthorhynchus desmursii , Aves: Furnariidae) based on mitochondrial and nuclear DNA

Parallelisms and paraphyletic assemblages are common among ovenbirds. Molecular markers are therefore the best approach when studying the evolutionary relationships among the members of this unparalleled diversified family. We obtained nucleotide sequence data from mitochondrial (cytochrome b) and nuclear genes (myoglobin and glyceraldehyde-3-phosphodehydrogenase) and used these to deduce the phylogenetic position of a monotypic genus endemic to the austral temperate rainforests of southern South America, the Des Murs’ Wiretail (Sylviorthorhynchus desmursii Des Murs, 1847, Aves: Furnariidae). Phylogenetic analyses based on maximum parsimony, maximum likelihood and Bayesian inference all converged into a congruent topology, with a basal position of Des Murs’ Wiretail within Synallaxinae together with Tit–Spinetails (Leptasthenura). Our data reject the hypothesis of a phylogenetic relationship between Des Murs’ Wiretail and thistletails (Schizoeaca) which exhibit parallelisms in morphology, tail structure and nest architecture. Using a molecular clock based on the myoglobin intron 2 gene, we estimated a divergence time of Des Murs’ Wiretail from Tit-Spinetails of 14–15 Myr, which is associated with the appearance of sclerophyllous forest elements in Chile at the Middle–Upper Miocene. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Genetic diversity and the biogeographical process of Acheilognathus macropterus revealed by sequence variations of mitochondrial cytochrome b gene

In this study, thirty-six individuals of Acheilognathus macropterus were collected from the Heilongjiang River, the Yangtze River, and the Nandujiang River. Partial mitochondrial cytochrome b gene region (636 base pair) was sequenced to these samples and 22 haplotypes were found. With A. chankaensis and A. tokinensis as outgroups, their relationships were analyzed. The p-distances were calculated with Mega software and a molecular phylogenetic tree was constructed using the neighbor-joining (NJ) method. The proportions of main morphological characters were compared as well. P-distances showed that the genetic differences in A. macropterus samples were far smaller than those between these samples and the outgroups. The molecular phylogenetic tree shows that samples with barbels and those without barbels were intermingled. There was no distinctive difference in proportions of morphological characteristics among them. These results suggested that samples with barbels and those without barbels (formally identified as A. taenianalis) are the same species; A. taenianalis is synonymous with A. macropterus. The thirtysix individuals were grouped into five clades and the positions of the samples in the clades were correspondingly grouped within their geographical distributions. Among the five clades, clades 1 and 5 included samples from the Heilongjiang River and Nandujiang River respectively. The samples from the Yangtze River scattered into clades 2, 3, and 4. There were distinctive genetic differences (>5%) among them. Interestingly, the distributions of the 21 samples in these three clades were not correlated to their geographical distributions. It is postulated that these genetic differences were due to the bitterlings’ mating choice mechanism, the prozygotic isolation. The genetic differences between the fish from Nandujiang River and those from the mainland indicated that they were separated early. However, the small genetic differences among the samples and the positions of the fish from the Heilonjiang River in the molecular phylogenetic tree indicate that fish in Heilongjiang River might have dispersed from the Yangtze River to that area much later. __________ Translated from Acta Hydrobiologica Sinica, 2006, 39(2): 134–140 [译自: 水生生物学报]     

Molecular Systematics of Chipmunks (<Emphasis Type="Italic">Neotamias</Emphasis>) Inferred by Mitochondrial Control Region Sequences

Western chipmunks (Neotamias) exhibit a complex geographical distribution and can vary by minute morphological differences. This has lead to confusion around the taxonomy and evolutionary history of this group. The main focus of this molecular study was to infer taxonomic relationships within Neotamias, especially at the tips of the tree. Sequences of the complete control region for 16 species of chipmunks (Tamias, Neotamias) were analyzed independently and in combination with previously published sequences of two mitochondrial genes, cytochrome b and cytochrome oxidase II. The control region data set corroborated the findings of Piaggio and Spicer (2001) in finding five discrete clades, while also providing stronger bootstrap support for most terminal branches. Analysis of individual mitochondrial genes revealed that not all genes have the same phylogenetic signal and when analyzed in combination, this incongruence amongst genes is resolved.     

Patterns of genetic differentiation in the <Emphasis Type="Italic">Gymnogeophagus gymnogenys</Emphasis> species complex,a neotropical cichlid from South American basins

The neotropical cichlid genus Gymnogeophagus is distributed in the Río de la Plata basin and in Dos Patos and Merín coastal lagoons on the border between Uruguay and southern Brazil. A phylogeographic approach based on mitochondrial cytochrome b analysis was performed to assess the patterns and processes of differentiation in this taxon. Gymnogeophagus gymnogenys showed high haplotype diversity (H = 0.992) and corrected mtDNA genetic distances ranged from 0 to 5.3%. Our analyses yielded robust support for the existence of four monophyletic groups within G. gymnogenys from the analyzed basins. No correlation between the aforementioned clades and geographic structure was found, since individuals belonging to different phylogenetic clades inhabit the same locality. The phylogeographic approach presented here showed that these four phylogroups (1, 2, 3 and 4) were sister groups. Our present findings would corroborate that G. gymnogenys could be integrated by different phylogenetic lineages, showing an explosive differentiation pattern and confirming the hypothesis that this taxon constitutes a species complex.     

<Emphasis Type="Italic">Strobilomyces verruculosus</Emphasis> sp. nov. from Japan

A new species, Strobilomyces verruculosus, is described and illustrated. It is morphologically distinct from other species of Strobilomyces by having a verruculose pileus with small subpyramidal scales, a long and thick stipe with small warty to appressed scales, subdecurrent tubes, and incompletely reticulate basidiospores. Molecular phylogenetic analyses using the mitochondrial cytochrome oxidase subunit 3 (cox3) gene support that it belongs to the genus Strobilomyces and is highly differentiated from the other members of this genus found in Japan.     

Molecular phylogeny and biogeography of langurs and leaf monkeys of South Asia (Primates: Colobinae)

The two recently proposed taxonomies of the langurs and leaf monkeys (Subfamily Colobinae) provide different implications to our understanding of the evolution of Nilgiri and purple-faced langurs. Groves (2001) [Groves, C.P., 2001. Primate Taxonomy. Smithsonian Institute Press, Washington], placed Nilgiri and purple-faced langurs in the genus Trachypithecus, thereby suggesting disjunct distribution of the genus Trachypithecus. [Brandon-Jones, D., Eudey, A.A., Geissmann, T., Groves, C.P., Melnick, D.J., Morales, J.C., Shekelle, M., Stewart, C.-B., 2003. Asian primate classification. Int. J. Primatol. 25, 97-162] placed these langurs in the genus Semnopithecus, which suggests convergence of morphological characters in Nilgiri and purple-faced langurs with Trachypithecus. To test these scenarios, we sequenced and analyzed the mitochondrial cytochrome b gene and two nuclear DNA-encoded genes, lysozyme and protamine P1, from a variety of colobine species. All three markers support the clustering of Nilgiri and purple-faced langurs with Hanuman langur (Semnopithecus), while leaf monkeys of Southeast Asian (Trachypithecus) form a distinct clade. The phylogenetic position of capped and golden leaf monkeys is still unresolved. It is likely that this species group might have evolved due to past hybridization between Semnopithecus and Trachypithecus clades.     

Molecular genetic variation across the southern and eastern geographic ranges of the African lion, <Emphasis Type="Italic">Panthera leo</Emphasis>

We examined sequence variation in the mitochondrial cytochrome b and NADH dehydrogenase subunit 5 genes (2,360 bp total) for 26 lions from eleven locations throughout sub-Saharan Africa. Six distinct haplotypes were observed in the combined sequences, forming two clades: the eastern and the western savannas. The Uganda-Western Kenya haplotype grouped at a basal position with the eastern clade of lions from Tsavo south to the Transvaal and Natal regions. The phylogenetic position of the haplotype from Sabi Sands in the southern part of Kruger National Park remained poorly resolved. The haplotypes found in Namibia and Botswana formed the western clade. The modest genetic variation documented here argues against taxonomic distinctions among living African lions.     

Structure and evolution of opossum,guinea pig,and porcupine cytochrome b genes

Summary We have sequenced the mitochondrial cytochrome b gene from the guinea pig, the African porcupine, and a South American opossum. A phylogenetic analysis, which includes 22 eutherian and four other vertebrate cytochrome b sequences, indicates that the guinea pig and the porcupine constitute a natural clade (Hystricomorpha) that is not a sister group to the clade of mice and rats (Myomorpha). Therefore, the hypothesis that the Rodentia is paraphyletic receives additional support. The artiodactyls, the perissodactyls, and the cetaceans form a group that is separated from the primates and the rodents. The 26 sequences are used to study the structure/function relationships in cytochrome b, whose function is electron transport. Most of the amino acid residues involved in the two reaction centers are well conserved in evolution. The four histidines that are believed to ligate the two hemes are invariant among the 26 sequences, but their nearby residues are not well conserved in evolution. The eight transmembrane domains represent some of the most divergent regions in the cytochrome b sequence. The rate of nonsynonymous substitution is considerably faster in the human and elephant lineages than in other eutherian lineages; the faster rate might be due to coevolution between cytochrome b and cytochrome c. Offprint requests to: W.-H. Li     

Use of mitochondrial and nuclear genes to infer the origin of two endemic pigeons from the Canary Islands

DNA nucleotide sequences from two mitochondrial genes (cytochrome b and NADH dehydrogenase subunit 2) and the nuclear intron 7 of β-fibrinogen were obtained to infer the phylogenetic origin of the two endemic Canarian pigeons: Bolle’s Pigeon (Columba bollii) and Laurel Pigeon (C. junoniae). Phylogenetic analyses of mitochondrial and nuclear genes based on maximum parsimony, maximum likelihood and Bayesian inference all converged into a congruent topology: C. bollii clusters together with the Wood Pigeon (C. palumbus) which is common in Europe and Asia, while C. junoniae was found near the base of the clade that includes other species of the genus Columba from the Old World. Laurel Pigeon probably represents an old lineage that might have colonized the Canary Islands a long time ago (20 My) while Bolle’s Pigeon might have arrived on the archipelago much later during the Upper Miocene (5 My). Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Molecular phylogeny of theChironomus genus deduced from nucleotide sequences of two nuclear genes,ssp 160 and the globin 2b gene

Two genes were employed to study phylogenetic relatedness of theChironomus species: the protein-coding, salivary gland-specificssp160 gene, and the globin 2b (gb2b) gene. By using PCR, it was demonstrated that all the 38Chironomus species analyzed possess thegb2b gene, while only 13 have thessp160 gene. Partial nucleotide sequences of the genes of 22 species were determined. The data obtained were employed to construct phylogenetic trees which appeared to be topologically similar and revealed five groups of phylogenetically closely related species. Combining the data obtained in the studies of nuclear and mitochondrial genes, a molecular-data-based scenario could be suggested for theChironomus genus evolution.     

Genetic variation of an endangered Malagasy frog, <Emphasis Type="Italic">Mantella cowani</Emphasis>, and its phylogeographic relationship to the widespread <Emphasis Type="Italic">M. baroni</Emphasis>

We investigated the degree and distribution of the genetic variation, and phylogeography, of two species of Malagasy poison frogs, Mantella cowani and M. baroni. The former is critically endangered due to its restricted distribution, habitat destruction and overcollection for the pet trade. Analysis of 526 bp of mtDNA (cytochrome b) resulted in separate haplotype networks for the two species, and discovered hybridization at a single locality. The two networks confirm the status of M. baroni and M. cowani as separate evolutionary species and units for conservation. Within both mitochondrial haplotype networks, specimens from different localities shared numerous identical haplotypes, even those from the most distant sample sites of M. baroni. Most populations were characterized by high haplotype diversity and no haplotype clades exclusive to geographical regions were observed. Protection of a few large populations of these species is therefore likely to conserve much of the mtDNA genetic diversity found in the entire species. While M. baroni is widespread and occurs in many nature reserves, we recommend efficient legal protection of some M. cowani habitats to protect this species against extinction.     

A molecular phylogeny of the Sylvia cantillans complex: cryptic species within the Mediterranean basin

The subalpine warbler Sylvia cantillans is formally considered a polytypic species, with four subspecies, European S. c. cantillans, albistriata, moltonii (recently resumed name: subalpina) and North African S. c. inornata. They are very similar in external morphology but clearly differ in their vocalizations. We evaluated their uncertain taxonomic status reconstructing the phylogenetic and phylogeographic relationships among populations sampled across major biogeographical areas in the European species’ range, using nucleotide sequences of the mitochondrial cytochrome b gene (mtDNA cyt b). A variety of phylogenetic analyses concordantly led to identify four major groups, only partially corresponding to the three European nominal subspecies. Phylogenetic trees showed a monophyletic group including all moltonii individuals, well diverged from all other taxa. Populations taxonomically assigned to cantillans were polyphyletic being split into two distinct clades (western and southern cantillans), with monophyletic albistriata closely related to southern cantillans. Individuals of moltonii and southern cantillans sampled in sites of sympatry in central Italy were assigned to their respective groups, with perfect concordance between phenotypic and genetic identifications. All findings indicate that moltonii should be ranked as a distinct species. Former subspecies cantillans is polyphyletic, but additional data are needed to define the taxonomic status of its two clades. Albistriata is phylogenetically related to southern cantillans and should be provisionally kept as a subspecies of S. cantillans. The cantillans complex thus provides an interesting case-study illustrating geographical structuring across small geographical ranges, and it exemplifies speciation through differentiation in allopatry leading to reproductive isolation after a secondary contact.     

Molecular phylogeny of the lionfish genera Dendrochirus and Pterois (Scorpaenidae, Pteroinae) based on mitochondrial DNA sequences

This study investigates the molecular phylogeny of seven lionfishes of the genera Dendrochirus and Pterois. MP, ML, and NJ phylogenetic analysis based on 964 bp of partial mitochondrial DNA sequences (cytochrome b and 16S rDNA) revealed two main clades: (1) “Pterois” clade (Pterois miles and Pterois volitans), and (2) “Pteropterus–Dendrochirus” clade (remainder of the sampled species). The position of Dendrochirus brachypterus either basal to the main clades or in the “Pteropterus–Dendrochirus” clade cannot be resolved. However, the molecular phylogeny did not support the current separation of the genera Pterois and Dendrochirus. The siblings P. miles and P. volitans are clearly separated and our results support the proposed allopatric or parapatric distribution in the Indian and Pacific Ocean. However, the present analysis cannot reveal if P. miles and P. volitans are separate species or two populations of a single species, because the observed separation in different clades can be either explained by speciation or lineage sorting. Molecular clock estimates for the siblings P. miles and P. volitans suggest a divergence time of 2.4–8.3 mya, which coincide with geological events that created vicariance between populations of the Indian and Pacific Ocean.     

Molecular Systematics of the Subfamily Caprinae (Artiodactyla, Bovidae) as Determined from Cytochrome b Sequences

We have sequenced the complete mitochondrial DNA cytochrome b gene from 18 species of the subfamily Caprinae and two outgroup taxa. Additional sequences retrieved from the literature were used to constitute a data set of 32 cytochrome b sequences comprising all genera usually included within the Caprinae. Phylogenetic relationships were assessed by PAUP using three new weighting schemes based on homoplasy analyses. Each type of substitution considered at each of the three codon positions was weighted according to its homoplasy level, as measured by the consistency index (CI), the slope of saturation (S), or their product (CIS). These differentially weighted parsimony analyses indicate that (1) the subfamily Caprinae is monophyletic, but only with the exclusion of Saiga from the group; (2) there is no support for monophyly of the four tribes currently recognized (Caprini, Rupicaprini, Ovibovini, and Saigini), suggesting relationships different from those traditionally accepted; (3) the caprine group consists of three major clades corresponding to (a) Budorcas and Ovis, (b) Capricornis, Ovibos, and Naemorhedus, and (c) Capra, Hemitragus, and Pseudois; and (4) the basal branching pattern is very weakly supported by bootstrap or branch support values except for the sister-group relationship of Pantholops with all other caprines, and the phylogenetic positions of Ammotragus, Oreamnos, and Rupicapra remain unclear.     

Mitochondrial phylogeography of baboons (Papio spp.) – Indication for introgressive hybridization?

Background  

Baboons of the genus Papio are distributed over wide ranges of Africa and even colonized parts of the Arabian Peninsula. Traditionally, five phenotypically distinct species are recognized, but recent molecular studies were not able to resolve their phylogenetic relationships. Moreover, these studies revealed para- and polyphyletic (hereafter paraphyletic) mitochondrial clades for baboons from eastern Africa, and it was hypothesized that introgressive hybridization might have contributed substantially to their evolutionary history. To further elucidate the phylogenetic relationships among baboons, we extended earlier studies by analysing the complete mitochondrial cytochrome b gene and the 'Brown region' from 67 specimens collected at 53 sites, which represent all species and which cover most of the baboons' range.