Elucidating the multiple genetic lineages and population genetic structure of the brooding coral <Emphasis Type="Italic">Seriatopora</Emphasis> (Scleractinia: Pocilloporidae) in the Ryukyu Archipelago

The elucidation of species diversity and connectivity is essential for conserving coral reef communities and for understanding the characteristics of coral populations. To assess the species diversity, intraspecific genetic diversity, and genetic differentiation among populations of the brooding coral Seriatopora spp., we conducted phylogenetic and population genetic analyses using a mitochondrial DNA control region and microsatellites at ten sites in the Ryukyu Archipelago, Japan. At least three genetic lineages of Seriatopora (Seriatopora-A, -B, and -C) were detected in our specimens. We collected colonies morphologically similar to Seriatopora hystrix, but these may have included multiple, genetically distinct species. Although sexual reproduction maintains the populations of all the genetic lineages, Seriatopora-A and Seriatopora-C had lower genetic diversity than Seriatopora-B. We detected significant genetic differentiation in Seriatopora-B among the three populations as follows: pairwise F _ST = 0.064–0.116 (all P = 0.001), pairwise G′′_ST = 0.107–0.209 (all P = 0.001). Additionally, only one migrant from an unsampled population was genetically identified within Seriatopora-B. Because the peak of the settlement of Seriatopora larvae is within 1 d and almost all larvae are settled within 5 d of spawning, our observations may be related to low dispersal ability. Populations of Seriatopora in the Ryukyu Archipelago will probably not recover unless there is substantial new recruitment from distant populations.     

Taxonomic and functional diversity in <Emphasis Type="Italic">Calogaya</Emphasis> (lichenised Ascomycota) in dry continental Asia

The genus Calogaya (Teloschistaceae, Xanthorioideae) was established to accommodate mainly epilithic lichens with lobate thalli, previously regarded as the “Caloplaca saxicola group.” Data supporting the recognition of this new genus came from European lichens, and although the genus is soundly based, we have found in Asia numerous epiphytic lineages and lineages with reduced, non-lobate thallus in dry continental areas. The taxonomic and functional diversity of Calogaya is distinctly higher in steppe and desert areas of Asia than in the less arid regions of Europe. We sampled 238 specimens, mostly from arid regions of north-western China, Iran, southern Siberia and Turkey. Three nuclear DNA loci were analysed separately and jointly by Bayesian inference, maximum likelihood and *BEAST approaches. Delimitations of 28 putative species were tested by BP&P multispecies coalescent model with joint analysis of species delimitation and species-tree estimation. Finally, we recognised 22 taxonomic units: 16 are at species rank, 3 are treated as subspecies and 3 are complexes, treated here as a single entity, but in reality probably including more than one species. Calogaya altynis, C. biatorina subsp. asiatica, C. decipiens subsp. esorediata, C. haloxylonis, C. orientalis, C. xanthoriella and C. xinjiangis are newly described. Caloplaca zoroasteriorum is combined into Calogaya, and Calogaya persica is reduced to a subspecies. The taxonomic status of Calogaya saxicola is unclear, and the name is employed here “sensu lato” for several non-monophyletic epilithic lineages with short-lobed thalli. Calogaya biatorina and C. ferrugineoides are the two other heterogeneous taxonomic units probably including more species.     

Incipient speciation in a neotropical Gesneriaceae: <Emphasis Type="Italic">Columnea kucyniakii</Emphasis> is nested within <Emphasis Type="Italic">C. strigosa</Emphasis>

Speciation is an ongoing process. Many recognized species are fully divergent from each other and their ancestors, whereas others are in earlier stages in the diversification process. Such incipient speciation may create patterns when one or a few populations are phenotypically distinct, but lack genomic level coalescence from each other or from their ancestral species. As a result, such progenitor-derivative species pairs are likely to lack reciprocal monophyly or generate paraphyletic ancestral species. Here we examine phylogenetic patterns in the Columnea strigosa (Gesneriaceae) complex to evaluate whether populations that have been named C. kucyniakii are reciprocally monophyletic with C. strigosa, its presumed ancestral species. Molecular phylogenetic results do not support reciprocal monophyly of the two species, implying that incipient speciation is occurring within the C. strigosa complex. We hereby recommend that C. kucyniakii be recognized at the specific rank despite the fact that it creates a paraphyletic C. strigosa. These findings bear importance in taxonomic decisions about paraphyletic taxa and recognizing evolutionary and morphologically distinct lineages.     

A geometric morphometric and microsatellite analyses of <Emphasis Type="Italic">Scaptotrigona mexicana</Emphasis> and <Emphasis Type="Italic">S. pectoralis</Emphasis> (Apidae: Meliponini) sheds light on the biodiversity of Mesoamerican stingless bees

Geometric morphometrics and molecular methods are effective tools to study the variability of stingless bee populations and species that merit protection given their worldwide decline. Based on previous evidence of cryptic lineages within the Scaptotrigona genus, we tested the existence of multiple evolutionary lineages within the species S. mexicana and we investigated the status of S. pectoralis. By analyzing their population structure, we found differences between the Pacific and Atlantic populations of each of these species, although geometric morphometrics of the wing only confirmed these results in S. mexicana. There was a tendency towards enhanced genetic differentiation over larger distances in the Atlantic populations of both species but not in the Pacific populations. These results revealed a pattern of differentiation among evolutionary units and a specific distribution of genetic diversity within these Scaptotrigona species in Mesoamerica, suggesting the need for future taxonomic revisions, as well as activities aimed at management and conservation.     

Phylogenetic reconstruction of the South American genus <Emphasis Type="Italic">Leucheria</Emphasis> Lag. (Asteraceae,Nassauvieae) based on nuclear and chloroplast DNA sequences

The genus Leucheria Lag. (Asteraceae Bercht. and J. Presl, tribe Nassauvieae Cass.) comprises 45 species and three infraspecific taxa distributed in the Andean region from southern Chile and Argentina to Peru. Six species are annual herbs. The genus has had a long taxonomic history involving the transference of species described originally under many different genera. The main objectives of this paper were to determine the phylogenetic relationships of species of Leucheria, examine the hypothesis that the ancestor of Leucheria would have originated in a forested habitat and examine the validity of nine morphologically defined evolutionary lines recognized in earlier work on the genus. Additionally we investigated whether the annual species of Leucheria are derived. We extracted DNA from leaf material for 45 taxa (94%) of Leucheria. We used Bayesian inference and plastid and nuclear genes to construct a phylogenetic hypothesis. Results show that Leucheria is monophyletic and is comprised of two main clades. One clade comprises perennial acaulescent/subacaulescent species, all with a solitary capitulum. We recognized three lineages in the second clade comprised of caulescent species that exhibit multiple capitula. Optimization of life-form over the phylogeny showed that five of the six annual species studied are derived in our tree. We conclude that the appearance of the annual habit is associated with the colonization of arid conditions in the winter rainfall coastal desert of northern Chile. Our result shows that species of Leucheria from forested habitats are derived. Discrepancies with previously recognized morphologically defined evolutionary lines were detected.     

<Emphasis Type="Italic">Disperis tomaszii</Emphasis> (Orchidaceae,Orchidoideae), a new species from Cameroon

Disperis tomaszii (Orchidaceae, Orchidoideae) from Cameroon is described and illustrated in this study. The new species is morphologically similar to Disperis nitida and Disperis thomensis. Phylogenetic analyses of selected DNA regions (ITS, matK) indicate a possible relationship between the new species and Disperis anthoceros and Disperis dicerochila. The taxonomic affinity between D. tomaszii and the aforementioned species is discussed.     

Ecomorph Evolution in <Emphasis Type="Italic">Myotis</Emphasis> (Vespertilionidae,Chiroptera)

The genus Myotis is unique among mammals in its high taxonomic diversity and global distribution. Their phylogenetic relationships reflect biogeographic affinities rather than phenotypes. Myotis diverged from other bats in the early Miocene, with a subsequent split between Old and New World lineages about 19 million years ago. Similar ecomorphs (‘Leuconoe’ [near-water hunters], ‘Myotis’ [gleaners], ‘Selysius’ [aerial hawkers]) emerged independently in different lineages of Myotis. We retrieved the probable ancestral ecomorph for each lineage. Phenetic diversity was estimated from the analysis of body and skull traits. It seems that evolution of Myotis fluctuated between ‘Leuconoe’, ‘Selysius’, and larger ‘Myotis’.     

Morphogenetic diversity of the ectomycorrhizal genus <Emphasis Type="Italic">Cortinarius</Emphasis> section <Emphasis Type="Italic">Calochroi</Emphasis> in the Iberian Peninsula

The taxonomic and genetic diversity of Cortinarius section Calochroi in one of the most biodiversity-rich regions in Europe, the Iberian Peninsula, was investigated through morphological and phylogenetic methods. This combined methodological approach allowed the identification of 15 known species and one new species, Cortinarius ortegae, which is described here. A dichotomous key is provided for field recognition of Calochroi species inhabiting different Iberian and Balearic Island woodlands. Polymorphism analyses within some studied species showed that the distribution of intraspecific lineages is dependent on geography and, in some cases, tree host. Furthermore, the dating analysis suggested that diversification within Calochroi started in the Pliocene and most of the current genetic diversity originated in the Pleistocene. This temporal scenario supports hypotheses in which climatic oscillations in the Quaternary may have been driving the evolution of this group of ectomycorrhizal fungi.     

Two new species of <Emphasis Type="Italic">Conidiobolus</Emphasis> occurring in Anhui,China

Two new species of Conidiobolus were isolated from Anhui Province, China. A polyphasic taxonomic approach comprising morphological characteristics and molecular data (the nuclear large subunit of ribosomal DNA and the translation elongation factor 1 alpha gene sequences) was applied to determine their novel taxonomic status in the genus Conidiobolus. The new species C. mirabilis is a sister group to C. thromoides, but morphologically differs by smaller primary conidia and a unique formation of zygospores among two to four adjacent hyphal segments. The other new species C. pachyzygosporus characterized with thick-walled zygospores is phylogenetically closely related to C. antarcticus, C. couchii, and C. osmodes.     

Different dispersal histories of lineages of the earthworm <Emphasis Type="Italic">Aporrectodea caliginosa</Emphasis> (Lumbricidae,Annelida) in the Palearctic

Earthworms are among the most abundant and ecologically important invasive species, and are therefore a good object for studying genetic processes in invasive populations. Aporrectodea caliginosa is one of the most widespread invasive earthworms in the temperate zone. It is believed to have dispersed from Europe to all continents except Antarctica. It is known that A. caliginosa consists of three genetic lineages, and genetic diversity is high both among and between them. We attempted to use that high genetic diversity to study A. caliginosa dispersal in the Palearctic based on a sample of 40 localities ranging from eastern Europe to the Russian Far East, and to compare our data to other studies on this species in western Europe and North America. Two genetic lineages were found in the studied sample. Only negligible decrease in genetic diversity was observed for the lineage 2 of A. caliginosa from West Europe to the Far East, suggesting multiple human-mediated introductions. In contrast, lineage 3 is abundant in West Europe and Belarus, but is absent from the East European Plain, the Urals, and the Far East. However, it is present in West Siberia, where it has greatly reduced genetic diversity, indicating long-distance dispersal accompanied by a bottleneck event. Thus, although these two lineages of A. caliginosa are morphologically indistinguishable, they have dramatic differences in their distributions and dispersal histories.     

Playing hide-and-seek with the tiny dragonfly: DNA barcoding discriminates multiple lineages of <Emphasis Type="Italic">Nannophya pygmaea</Emphasis> in Asia

We examined the utility of DNA barcode data for assessing genetic diversity of the tiny dragonfly Nannophya pygmaea Rambur in Asia. Data analyses inferred from the barcode region of cytochrome oxidase subunit I (COI) were performed with Malaysian N. pygmaea, along with the existing COI haplotypes distributed in Asia. We applied four species delimitation analyses [automatic barcode gap discovery (ABGD), generalised mixed yule coalescent (GMYC), poisson tree processes maximum likelihood (PTP_ML) and poisson tree processes simple heuristic solutions (PTP_sh)] to investigate potential lineages in this geographically widespread species. Based on our dataset, we provisionally recognize four distinct lineages or operational taxonomic units of N. pygmaea, which were represented by the taxa from Japan/Korea, China/Laos/Taiwan, Malaysia and Vietnam, respectively. Phylogenetic analyses showed two well-supported assemblages of N. pygmaea: one restricted to the taxa from Malaysia and Vietnam; and the other covering all populations further north (i.e., China, Japan, Korea, Laos and Taiwan). An extraordinarily high degree of genetic distance (up to >12 %) was detected between these two assemblages—suggesting they represent two separate species.     

Multi-approach analysis of the diversity in <Emphasis Type="Italic">Colletotrichum cliviae</Emphasis> sensu lato

Colletotrichum cliviae is a fungal species reported both as pathogen and endophyte with broad geographical distribution. Some purported isolates of this species have been assigned to different taxa, including Colletotrichum aracearum, Colletotrichum orchidearum and Colletotrichum. sichuanensis, for which a preliminary analysis of extensive multilocus (ACT, GAPDH, ITS, TUB2) data in this study revealed high sequence similarity with C. cliviae. We further reassessed the species delineation by using the coalescent method of the generalized mixed Yule-coalescent (GMYC) and Poisson Tree Processes (PTP). Single and multilocus gene trees strongly supported a C. cliviae s. lat. clade including the four species. This clade unfolded eight subclades grouped into three distinct lineages, but no monophyly of any of the four species. GMYC and PTP analyses confidently supported the evolutionary independence of these lineages. C. sichuanensis and C. cliviae, except one isolate, formed the largest lineage. The second lineage was made up of isolates named C. aracearum and some of C. orchidearum sharing the haplotype and the third lineage accommodated two isolates named C. cliviae and C. orchidearum. This finding suggests the synonymization of C. sichuanensis with C. cliviae whereas the taxonomic status of C. aracearum and C. orchidearum still needs clarification. This study lays great stress upon the use of comprehensive data for sequence-based characterisation of species in the C. cliviae s. lat. It also presents the first report of C. cliviae in tropical Africa and on citrus host.     

Molecular systematics of the critically-endangered North American spinymussels (Unionidae: <Emphasis Type="Italic">Elliptio</Emphasis> and <Emphasis Type="Italic">Pleurobema</Emphasis>) and description of <Emphasis Type="Italic">Parvaspina</Emphasis> gen. nov.

Despite being common in numerous marine bivalve lineages, lateral spines are extremely rare among freshwater bivalves (Bivalvia: Unionidae), with only three known species characterized by the presence of spines: Elliptio spinosa, Elliptio steinstansana, and Pleurobema collina. All three taxa are endemic to the Atlantic Slope of southeastern North America, critically endangered, and protected by the US Endangered Species Act. Currently, these species are recognized in two genera and remain a source of considerable taxonomic confusion. Because spines are rare in freshwater mussels and restricted to a small region of North America, we hypothesized that spinymussels represent a monophyletic group. We sequenced two mtDNA gene fragments (COI and ND1) and a fragment of the nuclear ITS-1 locus from >70 specimens. Bayesian and maximum-likelihood phylogenetic reconstructions suggest that the spinymussels do not comprise a monophyletic group. Elliptio steinstansana is sister to P. collina, forming a monophyletic clade that was estimated to have diverged from its most recent ancestor in the late Miocene and is distinct from both Elliptio and Pleurobema; we describe a new genus (Parvaspina gen. nov.) to reflect this relationship. Additionally, E. spinosa forms a monophyletic clade that diverged from members of the core Elliptio lineage in the mid-Pliocene. Furthermore, E. spinosa is genetically divergent from the other spinymussel species, suggesting that spines, while extremely rare in freshwater mussels worldwide, may have evolved independently in two bivalve lineages. Recognizing the genetic distinctiveness and inter-generic relationships of the spinymussels is an important first step towards effectively managing these imperiled species and lays the groundwork for future conservation genetics studies.     

Genetic distinctiveness of the damselfly <Emphasis Type="Italic">Coenagrion puella</Emphasis> in North Africa: an overlooked and endangered taxon

North African odonates are facing conservation challenges, not only by increased degradation and loss of habitat, but also by having poorly understood taxonomy. Coenagrion puella is a widely distributed damselfly but there is debate about the taxonomic status of North African populations, where the species is very rare. We evaluate the genetic distinctiveness of North African C. puella using mitochondrial and nuclear genetic markers. We found a clear genetic differentiation between North African and European populations (3.4 % mtDNA) and a lack of shared haplotypes between individuals from the two continents. These results suggest that the damselfly C. puella comprises two genetically distinct phylogenetic lineages: one in Europe and one in North Africa, and re-invigorate the debate on the validity of the North African endemic C. puella kocheri. We propose that these two lineages of C. puella should be managed as distinct molecular operational taxonomic units. More generally, this study reinforces the important role of North Africa as centre of speciation and differentiation for odonates, and highlights the relevance of incorporating genetic data to understand the evolutionary history and taxonomy for effective biodiversity conservation.     

Taxonomic delimitation of <Emphasis Type="Italic">Fulvifomes robiniae</Emphasis> (Hymenochaetales,Basidiomycota) and related species in America: <Emphasis Type="Italic">F. squamosus</Emphasis> sp. nov.

Morphological revision of Fulvifomes robiniae, as well as phylogenetic inferences based on nITS and nLSU markers, indicated that the species has a narrower concept in its morphology and distribution. Other morphologically related taxa arise from this taxonomic approach. Fulvifomes cedrelae is not accepted as a synonym of F. robiniae, and Fulvifomes squamosus sp. nov. is described as new based on Peruvian specimens. Based on morphology, phylogenetic relationships and host distributions, the taxonomic implication for the genus and other related taxa are discussed.