Molecular phylogeny and historical biogeography of the genus Platycerus (Coleoptera,Lucanidae) in East Asia

The genus Platycerus is a cool temperature zone taxon widely distributed in the Northern Hemisphere. In East Asia, 10, one and 28 species are known in Japan, Korea and China, respectively. Recent studies of Platycerus have revealed the divergence pattern in Japan and South Korea, but that of Chinese Platycerus is unknown. We conducted a phylogenetic and biogeographical study of Platycerus in East Asia, including China, using 68, 87 and 296 sequence data of the nuclear wingless gene, internal transcribed spacer (ITS) region and mitochondrial COI gene, respectively. Although the introgression of mitochondrial genes had been known in Japanese Platycerus, the essential contradiction was not recognized between the phylogenetic trees of nuclear genes and COI in Chinese Platycerus. In the COI tree, the Japanese clade and Asian continental clade diverged around 10.84 million years ago, and four major clades were recognized in the latter. For the shape of the posterolateral corner of the Platycerus pronotum, sharp (S)-type species are distributed in higher latitudinal and lower altitudinal areas than round (R)-type species in the Asian continent. S-type species have evolved from R-type species at least three times in more northerly areas, where the annual amplitude of temperature change is large. The genus Platycerus has been differentiated and speciated by a process unique to South Korea, Japan and China, according to regional topography. Thus, genetic differentiation and speciation in Platycerus are related to latitudinal and altitudinal gradients, as well as the site topographical profile and niche differentiation.     

DNA data and morphology suggest an occurrence of Dendrolimus sibiricus Tschetverikov, 1908 (Lepidoptera: Lasiocampidae) instead of D. superans Butler, 1877, in South Korea

In the present study, specimens of Dendrolimus superans collected from South Korea suggest the presence of D. sibiricus, instead of D. superans. Comparisons of the wing morphology, female and male genitalia, 3′‐end region of the cytochrome c oxidase I (COI) gene sequence, and internal transcribed spacer (ITS) 2 sequence of the Korean specimens with those of the D. superans specimens from Japan consistently supported the presence of D. sibiricus in South Korea. Phylogenetic analyses of the concatenated sequences of COI and ITS2 from the available sequence types of D. sibiricus and D. superans, along with South Korean specimens, were conducted using the Bayesian inference (BI) and maximum likelihood (ML) methods. These phylogenetic analyses placed the South Korean specimens with the Russian D. sibiricus as an inclusive group, excluding the Japanese D. superans, indicating the distribution of D. sibiricus in South Korea. Nevertheless, D. superans formed a distinct group only by BI analysis (Bayesian posterior probabilities = 0.89), whereas D. sibiricus, including the South Korean samples, formed a distinct group only by the ML analysis (99%), suggesting a low genetic divergence between the two species.     

Phylogenetic analysis based on multiple gene sequences revealing cryptic biodiversity in Simulium multistriatum group (Diptera: Simuliidae) in Thailand

Phylogenetic relationships among four species of the Simulium multistriatum group (Diptera: Simuliidae) in Thailand were examined based on two mitochondrial genes (COI, COII) and one nuclear gene (18S/ITS1). Simulium takense was found to be genetically divergent (>20.3% for COI) from the other species, consistent with their distinctive morphology. Simulium chainarongi and S. chaliowae were monophyletic but were included in paraphyletic S. fenestratum. Simulium fenestratum was divided into three distinct lineages with high levels of genetic divergence. This suggests that S. fenestratum is a species complex. Neither morphological nor cytological examinations revealed evidence of sibling species. The clades derived from phylogenetic analyses were found to be correlated with the ecological conditions of larval habitat. Therefore, ecological adaptation may have played a role in black fly diversification and evolution. These results suggest the use of integrated, multidisciplinary approaches for fully understanding black fly biodiversity and systematics.     

Gene flow between two closely related species in the acuticollis species group (Coleoptera: Lucanidae: genus Platycerus) near their distribution border based on morphology and mitochondrial gene

The male endophallic morphology and mitochondrial cytochrome oxidase subunit I (COI) gene of two parapatric species of the acuticollis species group, Platycerus acuticollis and P. albisomni, were examined at the border between the two species. No morphologically inferred hybrid was found. The endophallic and mitochondrial types of each individual were significantly linked, and the two species inferred by both types were essentially parapatric even at a very local level. We inferred that the reproductive isolation between them is high, although introgressive hybridization occurred rarely. The taxonomical assignment of P. acuticollis and P. albisomni as two distinct species is considered appropriate.     

Diversification process of stag beetles belonging to the genus Platycerus Geoffroy (Coleoptera: Lucanidae) in Japan based on nuclear and mitochondrial genes

Molecular phylogenies of the genus Platycerus in Japan were characterized based on the nuclear 28S ribosomal RNA and mitochondrial cytochrome oxidase subunit I (COI) genes. These analyses, combined with our previous morphological information, revealed a detailed diversification process of Platycerus in Japan, as well as estimates of their divergence times. Japanese species were monophyletic and were inferred to have diverged to the acuticollis species group and all other species ca 1.69 Mya. The acuticollis species group then appeared to split into P. viridicuprus and a group including P. takakuwai, P. albisomni and P. acuticollis ca 1.26 Mya. Other specific divergences have occurred primarily since ca 0.33 Mya. Comparing the molecular trees and the morphological tree, we also found introgression of the COI gene in some species. Genetic divergence of Platycerus has occurred intensely in southwestern Japan.     

Local ecological divergence of two closely related stag beetles based on genetic,morphological, and environmental analyses

The process of phenotypic adaptation to the environments is widely recognized. However, comprehensive studies integrating phylogenetic, phenotypic, and ecological approaches to assess this process are scarce. Our study aims to assess whether local adaptation may explain intraspecific differentiation by quantifying multidimensional differences among populations in closely related lucanid species, Platycerus delicatulus and Platycerus kawadai, which are endemic saproxylic beetles in Japan. First, we determined intraspecific analysis units based on nuclear and mitochondrial gene analyses of Platycerus delicatulus and Platycerus kawadai under sympatric and allopatric conditions. Then, we compared differences in morphology and environmental niche between populations (analysis units) within species. We examined the relationship between morphology and environmental niche via geographic distance. P. kawadai was subdivided into the “No introgression” and “Introgression” populations based on mitochondrial COI gene – nuclear ITS region discordance. P. delicatulus was subdivided into “Allopatric” and “Sympatric” populations. Body length differed significantly among the populations of each species. For P. delicatulus, character displacement was suggested. For P. kawadai, the morphological difference was likely caused by geographic distance or genetic divergence rather than environmental differences. The finding showed that the observed mitochondrial–nuclear discordance is likely due to historical mitochondrial introgression following a range of expansion. Our results show that morphological variation among populations of P. delicatulus and P. kawadai reflects an ecological adaptation process based on interspecific interactions, geographic distance, or genetic divergence. Our results will deepen understanding of ecological specialization processes across the distribution and adaptation of species in natural systems.     

Incongruence between morphological and molecular markers in the butterfly genus Zizina (Lepidoptera: Lycaenidae) in New Zealand

The butterfly genus Zizina in New Zealand has a complex taxonomic history due to the presence of morphological intermediates between the two species, the endemic Z. oxleyi and the introduced Z. labradus, in a putative hybrid zone on the east coast of the South Island of New Zealand. This makes species identification in the field problematic, particularly as the presence of hybrids has not been confirmed. We address this uncertainty through morphological and molecular analyses. Specimens were collected from a range of locations in New Zealand, as well as from Australia, and measurements were made of male genitalia and ventral wing coloration. Two mitochondrial genes (COI, ND5) and three nuclear gene fragments (28S, ITS2 and wingless) were also sequenced for a selection of individuals, and the presence of Wolbachia species in genomic DNA was tested. The two species were separable in morphological space, although there was some overlap, and the contact zone appeared to be around Kaikoura on the east coast of the South Island. Furthermore, specimens from the putative hybrid zone could be classified as Z. oxleyi using morphological characters individually, but not when these were used in a principal component analysis. Molecular analysis showed that there was a mean sequence divergence of 2.0% between two clades for COI, and 4.1% for ND5, but suggested that the contact zone between them was in the north‐west of the South Island. However, there was only a single clade for each of the three nuclear markers. It is thought that this incongruence between morphological and molecular markers is indicative of hybridization which is more extensive than previously thought. However, the possibility that recent speciation has occurred or is occurring is not ruled out.     

Recent emergence and worldwide spread of the red tomato spider mite, <Emphasis Type="Italic">Tetranychus evansi</Emphasis>: genetic variation and multiple cryptic invasions

Plant biosecurity is increasingly challenged by emerging crop pests. The spider mite Tetranychus evansi has recently emerged as a new threat to solanaceous crops in Africa and the Mediterranean basin, with invasions characterized by a high reproductive output and an ability to withstand a wide range of temperatures. Mitochondrial (868 bp of COI) and nuclear (1,137 bp of ITS) loci were analyzed in T. evansi samples spanning the current geographical distribution to study the earliest stages of the invasive process. The two sets of markers separate the samples into two main clades that are only present together in South America and Southern Europe. The highest COI diversity was found in South America, consistent with the hypothesis of a South American origin of T. evansi. Among the invaded areas, the Mediterranean region displayed a high level of genetic diversity similar to that present in South America, that is likely the result of multiple colonization events. The invasions of Africa and Asia by T. evansi are characterized by a low genetic variation associated with distinct introductions. Genetic data demonstrate two different patterns of invasions: (1) populations in the Mediterranean basin that are a result of multiple cryptic introductions and (2) emerging invasions of Africa and Asia, each likely the result of propagules from one or limited sources. The recent invasions of T. evansi illustrate not only the importance of human activities in the spread of agricultural pests, but also the limits of international quarantine procedures, particularly for cryptic invasions.     

Developing a new molecular marker for aphid species identification: Evaluation of eleven candidate genes with species-level sampling

The mitochondrial cytochrome c oxidase subunit I (COI) gene has been utilized as a molecular marker for aphid species identification. However, this gene has sometimes resulted in misidentification because of low interspecific genetic divergences between some species pairs. In this study, to propose new molecular markers for the family Aphididae, we first screened 2289 sequences of 11 genes (COI, COII, CytB, ATP6, lrRNA, srRNA, ITS1, ITS2, EF1a, 18S, and 28S) collected from the GenBank. Among the 11 genes, ATP6 gene revealed the largest genetic divergence among congeneric species with the smallest divergence among conspecific individuals; in contrast, species pairs with low genetic divergences (< 1%) were not observed. Secondly, for statistically testing the usefulness of ATP6 gene in species identification, we analyzed genetic distances between all of the combinations of 32 individuals of 20 species for both COI and ATP6 genes. The ATP6 gene showed lower intraspecific (on average 0.08%) and higher interspecific (on average 8.28%) genetic distances than the COI gene (on average 0.19% and 6.24%, respectively) for the same pairs of individuals. This study corroborates the usefulness of the ATP6 gene as a new molecular marker that could improve the misidentification problems that are inherent with the COI gene.     

Complete mitochondrial genome of the wild silkmoth,Saturnia boisduvalii (Lepidoptera: Saturniidae)

We sequenced mitochondrial genome (mitogenome) of the wild silkmoth, Saturnia boisduvalii (Lepidoptera: Saturniidae), which occurs in mainland Korea, and compared it with other species in Bombycoidea to characterize the genomic evolution of the superfamily. We found that the composition and arrangement of genes in the 15,257‐bp S. boisduvalii genome are typical of the majority of Lepidoptera, and the genome is biased toward A/T nucleotides, as previously reported. Comparison of individual gene divergence among bombycoid species showed that ND6 was most variable (p‐distance = 0.21), whereas COI and COII were most conserved, indicating that of all the protein‐coding genes (PCGs) ND6 appear to have evolved most rapidly. Thus, other PCGs beside COI are potential alternative markers, where scrutinized discrimination among species is required.     

Deep sympatric mtDNA divergence in the autumnal moth (Epirrita autumnata)

Deep sympatric intraspecific divergence in mtDNA may reflect cryptic species or formerly distinct lineages in the process of remerging. Preliminary results from DNA barcoding of Scandinavian butterflies and moths showed high intraspecific sequence variation in the autumnal moth, Epirrita autumnata. In this study, specimens from different localities in Norway and some samples from Finland and Scotland, with two congeneric species as outgroups, were sequenced with mitochondrial and nuclear markers to resolve the discrepancy found between mtDNA divergence and present species‐level taxonomy. We found five COI sub‐clades within the E. autumnata complex, most of which were sympatric and with little geographic structure. Nuclear markers (ITS2 and Wingless) showed little variation and gave no indications that E. autumnata comprises more than one species. The samples were screened with primers for Wolbachia outer surface gene (wsp) and 12% of the samples tested positive. Two Wolbachia strains were associated with different mtDNA sub‐clades within E. autumnata, which may indicate indirect selection/selective sweeps on haplotypes. Our results demonstrate that deep mtDNA divergences are not synonymous with cryptic speciation and this has important implications for the use of mtDNA in species delimitation, like in DNA barcoding.     

Molecular phylogeny and divergence time of the water penny genus Eubrianax (Coleoptera: Psephenidae) in Japan

The phylogenetic relationships among the Japanese members of the genus Eubrianax (Coleoptera: Psephenidae) were examined using the mitochondrial cytochrome oxidase subunit I (COI) gene and nuclear 28S rRNA gene sequences. Based on the molecular phylogeny as well as morphological features, the species status of Eubrianax brunneicornis Nakane, 1952 was proposed. The phylogenetic analyses recovered monophyly of the previously proposed pellucidus species group with four Japanese species, whereas a single Japanese species of the granicollis group was included in the lineage of the ramicornis group with five Japanese species. The divergence times of the species were estimated by dating the phylogenetic tree against the fossil record and a molecular clock based on the COI gene. The divergence of the Japanese species was inferred to have occurred during the Pliocene epoch.     

The gnd gene of Buchnera as a new,effective DNA barcode for aphid identification

DNA barcoding uses a standard DNA sequence to facilitate species identification. Although the COI gene has been adopted as the standard, COI alone is imperfect due to several shortcomings. The primary endosymbiont of aphids, Buchnera, has higher evolutionary rates and interspecies divergence than its co‐diverging aphid hosts, making it a potential tool for resolving the ambiguities in aphid taxonomy. We compared the effectiveness of employing two different DNA regions, gnd and COI, for the discrimination of over 100 species of aphids. The mean interspecific divergence of the gnd region was significantly higher than the mean intraspecific variation; there were nearly nonoverlapping distributions between the intra‐ and interspecific samples. In contrast, COI showed a lower interspecific divergence, which led to difficulties in identifying closely related species. Our results show that gnd can identify species in the Aphididae, which suggests that the gnd region of Buchnera is a potentially effective barcode for aphid species identification. We also recommend the 2‐locus combination of gnd + COI as the aphid barcode. This will provide a universal framework for the routine use of DNA sequence data to identify specimens and contribute toward the discovery of overlooked species of aphids.     

A molecular phylogeny of the Canidae based on six nuclear loci

We have reconstructed the phylogenetic relationships of 23 species in the dog family, Canidae, using DNA sequence data from six nuclear loci. Individual gene trees were generated with maximum parsimony (MP) and maximum likelihood (ML) analysis. In general, these individual gene trees were not well resolved, but several identical groupings were supported by more than one locus. Phylogenetic analysis with a data set combining the six nuclear loci using MP, ML, and Bayesian approaches produced a more resolved tree that agreed with previously published mitochondrial trees in finding three well-defined clades, including the red fox-like canids, the South American foxes, and the wolf-like canids. In addition, the nuclear data set provides novel indel support for several previously inferred clades. Differences between trees derived from the nuclear data and those from the mitochondrial data include the grouping of the bush dog and maned wolf into a clade with the South American foxes, the grouping of the side-striped jackal (Canis adustus) and black-backed jackal (Canis mesomelas) and the grouping of the bat-eared fox (Otocyon megalotis) with the raccoon dog (Nycteruetes procyonoides). We also analyzed the combined nuclear + mitochondrial tree. Many nodes that were strongly supported in the nuclear tree or the mitochondrial tree remained strongly supported in the nuclear + mitochondrial tree. Relationships within the clades containing the red fox-like canids and South American canids are well resolved, whereas the relationships among the wolf-like canids remain largely undetermined. The lack of resolution within the wolf-like canids may be due to their recent divergence and insufficient time for the accumulation of phylogenetically informative signal.     

Accelerated nrDNA evolution and profound AT bias in the medicinal fungus Cordyceps sinensis

Cordyceps sinensis is a reputed medicinal fungus growing parasitically on buried larvae of ghost moths in Asian high-altitude grassland ecosystems. We have analysed the intraspecific ITS nrDNA (ITS1, 5.8S gene, ITS2) variation among 71 sequences of C. sinensis available in EMBL/Genbank. The ITS sequences, submitted to Bayesian ML analyses, were distributed into five groups, referred to as A–E. Nine of the sequences (groups D and E) grouped with distantly related hypocrealean/clavicipitalean taxa and are interpreted as sequences erroneously accessioned under wrong taxon names. The remaining 62 sequences constituted three highly supported clades (groups A–C), that may represent cryptic (phylogenetic) species currently ascribed to C. sinensis. A remarkably high sequence divergence occurred in the 5.8S gene between the three groups. Sequences of groups B and C showed accelerated substitution rates and high AT nucleotide bias. We hypothesize that the accelerated evolution and AT bias have been caused by a shift in life historical attributes or ecology. We also suggest that the recorded differences in medicinal effects among C. sinensis populations may be attributed to the existence of genetically differentiated chemotypes in this morphotaxon.     

Pallenopsis patagonica (Hoek, 1881) – a species complex revealed by morphology and DNA barcoding,with description of a new species of Pallenopsis Wilson, 1881

Pallenopsis patagonica (Hoek, 1881) is one of the most taxonomically problematic and variable pycnogonid species, and is distributed around the southern South American coast, and the Subantarctic and Antarctic areas. We conducted a phylogenetic analysis of mitochondrial cytochrome c oxidase subunit I (COI) sequences of 47 Pallenopsis specimens, including 39 morphologically identified as P. patagonica, five Pallenopsis pilosa (Hoek, 1881), one Pallenopsis macneilli Clark, 1963, one Pallenopsis buphtalmus Pushkin, 1993, and one Pallenopsis latefrontalis Pushkin, 1993. Furthermore, we studied morphological differences between the different COI lineages using light and scanning electron microscopy, including also material from Loman's and Hedgpeth's classical collections, as well as Hoek's type material of P. patagonica from 1881. The molecular results unambiguously reveal that P. patagonica is a complex of several divergent clades, which also includes P. macneilli, P. buphtalmus, and P. latefrontalis. Based on the material available, two major clades could be identified, namely a ‘Falkland’ clade, to which we assign the nominal P. patagonica, and a ‘Chilean’ clade, which is distinct from the ‘Falkland’ clade. We describe the ‘Chilean’ clade as new species, P allenopsis yepayekae sp. nov. Weis, 2013. All molecular results are confirmed by specific morphological characteristics that are discussed in detail and compared with Pallenopsis species closely related to the P. patagonica complex. Our results reveal that P. patagonica is a species‐rich complex that is in need for a thorough taxonomic revision, using both morphological and genetic approaches. © 2014 The Linnean Society of London     

Phylogenetic relationships among populations of the Nacobbus aberrans (Nematoda,Pratylenchidae) complex reveal the existence of cryptic species

The plant‐parasitic nematode Nacobbus aberrans sensu lato is an agricultural pest of quarantine importance. Due to the morphometric, physiological and genetic variability observed within the species, there is no agreement on the taxonomy of this nematode. The objective of this study was to analyse the ITS rDNA region and the D2–D3 expansion segments of 28S rDNA in 10 Argentine populations and one from Ecuador and to establish their phylogenetic relationship with other known sequences from South and North America. Phylogenetic trees of the ITS gene showed seven statistically well‐supported clades; the high and significant F_st values obtained among these groups confirmed this partitioning. The Argentine populations here considered were separated into three clades: one comprising a population from the Andean region and two grouping nematodes from lower altitudes. Three other clades were distinguished for South American populations, which included known sequences of individuals from Peru, Bolivia and north of Argentina. The other clade included sequences from Mexico, Ecuador and two Argentine populations of unknown origin. The important degree of genetic divergence observed among Andean populations suggests that the Andes may have played a crucial role in speciation of Nacobbus, which would have originated in this region. Although D2–D3 segments exhibited lower variation, they were useful for establishing phylogenetic relationships among the Argentine populations considered in this work. As there are no other GenBank sequences available for these segments, it was not possible to make comparisons with other populations from South and North America. The considerable genetic differentiation observed in ITS rDNA region among Nacobbus populations showed evidence of cryptic species within the N. aberrans s.l. complex. Integration of morphological and morphometric studies and molecular analyses considering other genes may aid in the identification of species and their phylogenetic relationships within this genus.     

Cryptic species of <Emphasis Type="Italic">Notophyllum</Emphasis> (Polychaeta: Phyllodocidae) in Scandinavian waters

The phyllodocid polychaete Notophyllum foliosum occurs in two colour morphs in Swedish and Norwegian waters, one palish yellow to grey form with black patches that is restricted to deeper waters and often associated with reefs of the deep-water coral Lophelia pertusa, and one usually yellow-orange form with black patches and white spots that is usually encountered on more shallow bottoms. We have sampled the two forms from sympatric occurrences in Norway, and the shallow form from the Swedish west coast. Phylogenetic and haplotype analyses based on the mitochondrial cytochrome c oxidase subunit I (COI) gene and the nuclear internal transcribed spacer region (ITS1-5.8SrDNA-ITS2) unequivocally indicate that the two forms represent different species. We apply the name N. foliosum (Sars, 1835) to the ‘shallow form’, and propose N. crypticum n. sp. for the ‘deep form’. A lectotype is fixed for N. foliosum.