AFLPs resolve cytonuclear discordance and increase resolution among barcheek darters (Percidae: Etheostoma: Catonotus)

The use of mitochondrial DNA (mtDNA) sequences in phylogenetic analysis has been the subject of increasing scrutiny. A recent phylogenetic study of barcheek darters (Percidae: Etheostoma: Catonotus) revealed cytonuclear discordance, discordance among mtDNA loci, and discordance between mtDNA and morphometric hypotheses. In particular, mtDNA analyses hypothesized a paraphyletic barcheek darter clade, and a combined mtDNA and nuclear sequence topology was not well resolved. Here, we used amplified fragment length polymorphisms to test the monophyly of barcheek darters and to resolve relationships within the group. By including multiple populations of each species, we were able to generate a highly resolved tree that supports both the monophyly of barcheek darters as well as recently elevated species within the group. Analysis of three mtDNA loci indicates that saturation of highly variable sites best explains the discordant topologies among mtDNA partitions.     

Life history tactics of darters (Percidae: Etheostomatiini) and their relationship with body size, reproductive behaviour, latitude and rarity

Patterns of covariation of life history traits of darters in the genus Etheostoma are reviewed. The primary pattern is associated with body size. Large darters grow faster, mature at a larger size, produce bigger clutches, and have longer reproductive and life spans, and shorter spawning seasons, than do small darters. When the effects of size are removed statistically, the dominant secondary pattern matched the r-K continuum from fast-growing, short-lived, primarily semelparous species with many small ova and a high reproductive effort (r-species) to slow-growing, long-lived, iteroparous species with few large ova and a low reproductive effort (K-species). Variation in life history traits is also influenced by reproductive behaviour, latitude, and rarity (as measured by geographic range). There are significant differences in the primary and secondary life history patterns among reproductive guilds. Latitude and rarity are not correlated with these primary and secondary patterns. Instead, they account for variation of tertiary patterns. Rare species may not match the reproductive performance of more common and widely distributed species. Future studies of life history traits in darters should focus on species whose reproductive behaviour differs from that of the species reviewed in this study, and on the demographic characteristics of rare or declining populations.     

Phylogenetic relationships among Boleosoma darter species (Percidae: Etheostoma)

Darters represent a species rich group of North American freshwater fishes studied in the context of their diverse morphology, behavior, and geographic distribution. We report the first molecular phylogenetic analyses of the Boleosoma darter clade that includes complete species sampling. We estimated the relationship among the species of Boleosoma using DNA sequence data from a mitochondrial (cytochrome b) and a nuclear gene (S7 ribosomal protein intron 1). Our analyses discovered that the two Boleosoma species with large geographic distributions (E. nigrum and E. olmstedi) do not form reciprocally monophyletic groups in either gene trees. Etheostoma susanae and E. perlongum were phylogenetically nested in E. nigrum and E. olmstedi, respectively. While analysis of the nuclear gene resulted in a phylogeny where E. longimanum and E. podostemone were sister species, the mitochondrial gene tree did not support this relationship. Etheostoma vitreum was phylogenetically nested within Boleosoma in the mitochondrial DNA and nuclear gene trees. Our analyses suggest that current concepts of species diversity underestimate phylogenetic diversity in Boleosoma and that Boleosoma species likely provide another example of the growing number of discovered instances of mitochondrial genome transfer between darter species.     

Assessing phylogenetic resolution among mitochondrial, nuclear, and morphological datasets in Nothonotus darters (Teleostei: Percidae)

External morphological characters are the basis of our understanding of diversity and species relationships in many darter clades. The past decade has seen the publication of many studies utilizing mtDNA sequence data to investigate darter phylogenetics, but only recently have nuclear genes been used to investigate darter relationships. Despite a long tradition of use in darter systematics few studies have examined the phylogenetic utility of external morphological characters in estimating relationships among species in darter clades. We present DNA sequence data from the mitochondrial cytochrome b (cytb) gene, the nuclear encoded S7 intron 1, and discretely coded external morphological characters for all 20 species in the darter clade Nothonotus. Bayesian phylogenetic analyses result in phylogenies that are in broad agreement with previous studies. The cytb gene tree is well resolved, while the nuclear S7 gene tree lacks phylogenetic resolution, node support, and is characterized by a lack of reciprocal monophyly for many of the Nothonotus species. The phylogenies resulting from analysis of the morphological dataset lack resolution, but nodes present are found in the cytb and S7 gene trees. The highest resolution and node support is found in the Bayesian combined data phylogeny. Based on our results we propose continued exploration of the phylogenetic utility of external morphological characters in other darter clades. Given the extensive lack of reciprocal monophyly of species observed in the S7 gene tree we predict that nuclear gene sequences may have limited utility in intraspecific phylogeographic studies of Nothonotus darters.     

Phylogenetic relationships among four members of Stizostedion (Percidae) determined by mitochondrial DNA and allozyme analyses

Phylogenetic relationships among four Stizostedion species were examined using mitochondrial DNA (mtDNA) and allozyme analyses. Twenty-six allozyme loci were scored, and mtDNA variation was examined using 24 restriction endonucleases, yielding 48–57 restriction sites among the species. Genetic distance analyses show that the two North American species ( S. canadense and S. vitreum ) cluster in one group, while the two European species ( S. hciopercu and S. vogense ) form a second group. Nei's genetic distance between these two groups was 0.7 ± 0.2 for allozymes, while the corresponding mtDNA sequence divergence was 14.8 ± 2.0%, suggesting that these two groups diverged approximately 10 million years ago. Thus, these data are consistent with the hypothesis that Stizostedion colonized North America during the Pliocene.     

AFLP analysis of phylogenetic relationships among myrmecophytic species of Macaranga (Euphorbiaceae) and their allies

The palaeotropic pioneer tree genus Macaranga Thouars (Euphorbiaceae) is characterized by various types of mutualistic interactions with specific ant partners (mainly Crematogaster spp.). About 30 species are obligate ant-plants (myrmecophytes). We used amplified fragment length polymorphism (AFLP) markers to assess phylogenetic relationships among 108 Macaranga specimens from 43 species, including all available taxa from the three sections known to contain myrmecophytes. Eight primer combinations produced 426 bands that were scored as presence/absence characters. Banding patterns were analyzed phenetically, cladistically and by principal coordinates analysis. Monophyly of section Pruinosae is clearly supported. There is also good evidence for a monophyletic section Pachystemon that includes the puncticulata group. The monophyly of section Winklerianae and relationships between the three sections remain ambiguous. Section Pachystemon is subdivided into four well-supported monophyletic subclades that presumably correspond to taxonomic entities.We acknowledge the support by the Deutsche Forschungsgemeinschaft (DFG Fi606/4-1, DFG We1830/2-1, 4-1 and 4-2), which in part was granted in the frame of the DFG-SPP 1127 Radiations: origins of biological diversity. Part of the plant material was kindly supplied by Dr. H. Feldhaar (University of Würzburg), Dr. U. Moog (University of Kassel) and Dr. F. Slik (Leiden University Branch, Nationaal Herbarium Nederland). We thank the University of Malaysia (Dr. Rosli b. Hashim) and Taman Taman Sabah (Datuk Lamri Ali; Dr. J. Nais) for permits and logistic support, and EPU for permission to conduct research in Malaysia.     

Major discrepancy between phylogenetic hypotheses based on molecular and morphological criteria within the Order Haplosclerida (Phylum Porifera: Class Demospongiae)

Taxonomy within the sponge Order Haplosclerida remains somewhat contentious. Both morphology and biochemistry have been employed to help unravel the relationships of the Order with limited results perhaps because of the small number of reliable characters. We employed phylogenetic analysis of 750 base pairs of the 5′ end of the 28S rRNA gene to study relationships between 20 taxa within the Order. While preliminary (low number of taxa, one gene region) results suggested strong discrepancy to former phylogenies, there was no support for the monophyly of the Order and almost all morphologically defined genera appeared to be polyphyletic.     

AFLPs are incompatible with RAPD and morphological data in Pennisetum purpureum (Napier grass)

Accessions of Pennisetum purpureum in agricultural research centres in sub-Saharan Africa were genotyped using Amplified Fragment Length Polymorphisms (AFLPs) using primer combinations MluI/MseI. Cluster analyses of resulting bands suggested that the samples could be grouped into five large and five small-sized clusters. Principal coordinate analysis revealed two major clusters being well separated, with bulk of the samples forming one, poorly structured cluster. Our analyses failed to reveal the regional groupings found in previous studies using a subset of our sample universe and based on RAPDs as well as morphological and agronomical data. The inability of the AFLP data to clearly demarcate accessions is ascribed to either the presence of high levels of genetic uniformity, or non-optimal primers and/or bad germplasm management practices. The re-registration of all accessions, based on DNA barcoding, is suggested as a means to resolve the lingering problems regarding the identity of accessions.     

Phylogenetic relationships and divergence times of Charadriiformes genera: multigene evidence for the Cretaceous origin of at least 14 clades of shorebirds

Comparative study of character evolution in the shorebirds is presently limited because the phylogenetic placement of some enigmatic genera remains unclear. We therefore used Bayesian methods to obtain a well-supported phylogeny of 90 recognized genera using 5 kb of mitochondrial and nuclear sequences. The tree comprised three major clades: Lari (gulls, auks and allies plus buttonquails) as sister to Scolopaci (sandpipers, jacanas and allies), and in turn sister to Charadrii (plovers, oystercatchers and allies), as in previous molecular studies. Plovers and noddies were not recovered as monophyletic assemblages, and the Egyptian plover Pluvianus is apparently not a plover. Molecular dating using multiple fossil constraints suggests that the three suborders originated in the late Cretaceous between 79 and 102 Mya, and at least 14 lineages of modern shorebirds survived the mass extinction at the K/T boundary. Previous difficulties in determining the phylogenetic relationships of enigmatic taxa reflect the fact that they are well-differentiated relicts of old, genus-poor lineages. We refrain from suggesting systematic revisions for shorebirds at this time because gene trees may fail to recover the species tree when long branches are connected to deep, shorter branches, as is the case for some of the enigmatic taxa.     

18S rDNA AND EVOLUTION IN THE DASYCLADALES (CHLOROPHYTA): MODERN LIVING FOSSILS1

Phylogenetic relationships were inferred from parsimony and distance analyses of nuclear small-subunit ribosomal DNA sequences taken from 14 species representing 8 of the 11 extant genera in the Dasycladales. Of 1733 aligned positions, 412 (23.8%) were variable and 251 (61%) of those were phylogenetically informative within the Dasycladales. Secondary structure was analyzed and taken into account during all phases of data analysis. Robustness of the trees was assessed using bootstrap analysis and g₁ statistics of tree-length decay. Strongly supported branches were robust to all methods of analysis regardless of weighting schemes used. The secondary structure of the 18S within the Dasycladales agrees with that of other green algae with the exception of a shared deletion in stemloop E10-1 (ca. 13 nucleotides long), which provides additional support for the uniqueness of this monophyletic group. A molecular clock was calibrated from the dasyclad fossil record and suggests a radiation of the Acetabulariaceae at 120 ± 30 million years (Ma) ago and the Dasycladaceae 215 ± 40 Ma ago. The split of the two lineages from a shared ancestor is estimated at 265 ± 50 Ma ago. Within the Dasycladaceae, Neomeris and Cymopolia are sister taxa, as are Batophora and Chlorocladus. Bornetella groups with the Neomeris and Cymopolia clade in 78% of the bootstrap replicates. Relationships among the Acetabulariaceae show that Acetabularia and Polyphysa do not form monophyletic groups as presently circumscribed. No evidence indicates that Acicularia is the oldest genus. Halicoryne, Chalmasia, and Dasycladus were not included in the analysis. Molecular data provide afresh background perspective from which to discuss the evolution of one of the most ancient lineages of green plants.     

Rapidly evolving lineages impede the resolution of phylogenetic relationships among Clitellata (Annelida)

The phylogenetic relationships of the Clitellata were investigated using a data set with published and new complete or partial 18S rRNA and mtCOI gene sequences of 13 and 49 taxa representing 8 and 14 families, respectively. Three different alignments were considered for 18S, and the possible influence of departures from rate constancy among sites was evaluated by analyses using a Gamma model of rate heterogeneity. Maximum-likelihood estimates of the shape parameter alpha of the Gamma distribution were very low, whatever the alignment or the gene considered, suggesting that phylogenetic reconstructions taking into account the rate heterogeneity among sites are likely to be the most reliable. Analyzed separately, the two genes did not resolve the relationships among the Clitellata, but the consensus tree was congruent with the morphology-based relationships. Our data suggest the inclusion of the Euhirudinea, Acanthobdellida, and Branchiobdellida in the Oligochaeta and suggest the Lumbriculidae as the link between both assemblages. Although separate analyses of both genes, as well as different alignments for the 18S rRNA sequences, yielded conflicting results concerning the phylogenetic position of leeches and leech-like worms vis-à-vis the Oligochaeta, subsequent analyses using the Gamma model greatly reduced the observed inconsistencies. Our analyses show that among the Clitellata, the leeches and the leech-like and gutless worms represent significantly faster evolving lineages. It is suggested that the observed higher mutation rates may be explained by the fact that these lineages contain almost exclusively commensal and/or parasitic taxa.     

Free from mitochondrial DNA: Nuclear genes and the inference of species trees among closely related darter lineages (Teleostei: Percidae: Etheostomatinae)

Investigations into the phylogenetics of closely related animal species are dominated by the use of mitochondrial DNA (mtDNA) sequence data. However, the near-ubiquitous use of mtDNA to infer phylogeny among closely related animal lineages is tempered by an increasing number of studies that document high rates of transfer of mtDNA genomes among closely related species through hybridization, leading to substantial discordance between phylogenies inferred from mtDNA and nuclear gene sequences. In addition, the recent development of methods that simultaneously infer a species phylogeny and estimate divergence times, while accounting for incongruence among individual gene trees, has ushered in a new era in the investigation of phylogeny among closely related species. In this study we assess if DNA sequence data sampled from a modest number of nuclear genes can resolve relationships of a species-rich clade of North American freshwater teleost fishes, the darters. We articulate and expand on a recently introduced method to infer a time-calibrated multi-species coalescent phylogeny using the computer program ^*BEAST. Our analyses result in well-resolved and strongly supported time-calibrated darter species tree. Contrary to the expectation that mtDNA will provide greater phylogenetic resolution than nuclear gene data; the darter species tree inferred exclusively from nuclear genes exhibits a higher frequency of strongly supported nodes than the mtDNA time-calibrated gene tree.     

The potential of AFLPs in biosystematics: A first application inSolanum taxonomy(Solanaceae)

Using the AFLP technique highly informative DNA fingerprints were generated from 19 taxa ofSolanum sect.Petota (potatoes) and three taxa ofSolanum sect.Lycopersicum (tomatoes). Both phenetic and cladistic analyses were conducted from the individual genotypic level to the species level. An AFLP fingerprint, using a combination of suitable AFLP primers, generated 12 to 71 scorable fragments per genotype which was sufficient for taxonomic interpretation. The classifications based on the molecular markers were generally in agreement with current taxonomic opinions. Unexpectedly,S. microdontum was associated with ser.Megistacroloba rather than with ser.Tuberosa, andS. demissum (ser.Demissa) and species of ser.Acaulia appeared closely affiliated. AFLP is an efficient and reliable technique to generate biosystematic data and therefore a promising tool for evolutionary studies.     

Molecular phylogenetics of Uvaria (Annonaceae): relationships with Balonga,Dasoclema and Australian species of Melodorum

An extended molecular phylogenetic analysis of Uvaria (Annonaceae) is presented, using maximum parsimony, maximum likelihood and Bayesian methods, based on sequences of four plastid DNA regions (matK, psbA‐trnH spacer, rbcL and trnL‐F). The additional taxa include the monotypic West African genus Balonga, the monotypic South‐East Asian genus Dasoclema and seven Australian representatives of the genus Melodorum. The results indicate that all of these taxa are nested within a well‐supported clade otherwise consisting of Uvaria species, indicating that their taxonomic treatment needs to be reassessed. The distinguishing morphological characteristics of the taxa are re‐evaluated and interpreted as specialized adaptations of the basic Uvaria structure. The genus Uvaria is accordingly extended following the transfer of these species, necessitating six new nomenclatural combinations and two replacement names. © 2010 The Linnean Society of London, Botanical Journal of the Linnean Society, 2010, 163 , 33–43.     

Phylogenetic relationships among the microgastroid wasps (Hymenoptera: braconidae): combined analysis of 16S and 28S rDNA genes and morphological data

Relationships among the microgastroid complex of braconid wasps were investigated using sequence data from the 16S mitochondrial rDNA and 28S (D2 expansion region) nuclear rDNA genes, as well as morphological data. Parsimony analysis of these gene fragments, both separately and combined, indicated that Neoneurus (Neoneurinae) and Ichneutes (Ichneutinae) were no more closely related to the microgastroids than were a range of helconoid taxa. Combined parsimony analysis of the microgastroids indicated the relationships ((Cardiochilinae + Microgastrinae) + Miracinae) + Cheloninae, with Adeliinae falling inside the Cheloninae. Bootstrap proportions for each of these nodes were greater than 70%. Character reweighting (sensu Farris), using the rescaled consistency index, also recovered these relationships. Mapping of lifestyle traits onto this relatively well supported phylogeny indicated that solitary endoparasitism is ancestral for the microgastroids, with a single origin for egg-larval endoparasitism in the Cheloninae + Adeliinae. Mapping of the radiation of the microgastroids into lepidopteran hosts was less clear, due to the specialized biology of the most basal microgastroid clade, the Cheloninae + Adeliinae. Our data are consistent with attack of concealed lepidopteran hosts as the plesiomorphic lifestyle, at least for the Miracinae + Cardiochilinae + Microgastrinae, with radiation into more exposed hosts in the Cardiochilinae + Microgastrinae.     

Amplified Fragment Length Polymorphisms (AFLPs) detected with non-radioactive digoxigenine labelled primers in three plant species

A protocol for the detection of AFLPs with the non radioactive digoxigenine labelling is presented. The protocol has been tested on DNA samples from three different plant species. The AFLP technique was used for the first time in these species. The sensitivity and reliability of the digoxigenine labelled primers in the AFLP technique was of the same order as the sensitivity and reliability of the radioactive assay. No major adjustments of the current standard AFLP protocols is necessary to use the digoxigenine labelled primers.     

Phylogenetic relationships among the phyllotini (rodentia: Sigmodontinae) using morphological characters

Thirty-three species representing all 14 genera of the South American rodent tribe Phyllotini and 5 problematic genera are surveyed for 96 multistate and binary dental, cranial, skeletal, external, and male reproductive tract characters. Wagner parsimony analysis confirmsCalomys as the most basal phyllotine genus, and as currently constituted it is likely paraphyletic. The results are consistent with the exclusion ofPseudoryzomys from the phyllotines and the separation ofReithrodon andNeotomys fromHolochilus at the tribal level. Several highly differentiated generic groups that include a radiation of altiplano endemics centered onAuliscomys and the largely southern Andean/PatagonianReithrodon group appear to form a clade. AGraomys generic group that includesAndalgalomys andEligmodontia is also apparent, but its relationships to other phyllotines are obscured by poorly resolved internal nodes in the more species-rich and probably paraphyletic genusPhyllotis. The significance and consequences of more intensive taxonomic sampling are discussed. The taxonomic consequences of the phylogeny are presented.     

Origin and diversification of Thymelaea (Thymelaeaceae): inferences from a phylogenetic study based on ITS (rDNA) sequences

Thymelaea is a Mediterranean genus belonging to a primarily tropical and subtropical family. This genus is here presented as a particular case on which the hypothesis of an in situ evolution of the Mediterranean flora from a Tertiary subtropical stock can be phylogenetically tested. To better understand the evolutionary history of Thymelaea, molecular phylogenies based on ITS (rDNA) sequences are estimated. Phylogenetic analyses strongly support the monophyly of Thymelaea and the sister position of Daphne. Unexpected relationships between sequences of T. granatensis, T. pubescens and T. sanamunda are found and explained as a case of cryptic nuclear introgression. Phylogenetic analyses also reveal the polyphyletic character of Diarthron, sensu Tan, suggesting that Dendrostellera and Stelleropsis should be reinstated as independent genera. Based on the resulting phylogenetic hypothesis and using statistical tests it is suggested that Thymelaea experienced an initial rapid diversification. Time estimates for the origin and radiation of Thymelaea based on independent sources of evidence—paleontological, paleoclimatic and paleogeographic data, on one hand, and ITS substitution rates reported for other angiosperm groups, on the other—give strikingly similar results. The early radiation of Thymelaea is inferred to have occurred in the Upper Miocene, after this lineage diverged from that of Daphne in the Lower or Middle Miocene. Both evolutionary events are related to the overall climatic deterioration (declining temperature and increasing dryness) registered throughout the Miocene in Eurasia. The rapid and extensive diversification of Thymelaea is placed in the Iberian Peninsula or here and in the neighbouring North African territory.     

Phylogenetic relationships among the lepidopteran and trichopteran suborders (Insecta) from the embryological standpoint1

Adopting the cladistic method in comparative embryology, 27 embryonic characters were analyzed to reconstruct the phylogenetic relationships among the lepidopteran and trichopteran suborders, viz., Annulipalpia, Integripalpia, Zeugloptera, Dacnonypha, Exoporia, Monotrysia, and Ditrysia. The resultant cladogram is basically coincident with that proposed by Kristensen . The order Trichoptera and Lepidoptera constitute a monophyletic group on the basis of one synapomorphy, the presence of well developed silk glands in embryos. The Trichoptera are separable from the Lepidoptera by the states of four characters. The Trichoptera, as a whole, are quite homogenous, and embryological data provide no rational ground for the separation of this order into the Annulipalpia and Integripalpia at a subordinal level. On the contrary, the embryonic development of the Lepidoptera becomes divergent from the most primitive condition to a specialized one according to suborders. The Zeugloptera are the sister group of all other Lepidoptera, because they share two apomorphies with the latter. The Dacnonypha are the most primitive next to the Zeugloptera, and have a sister-group relationship with the Exoporia + (Monotrysia + Ditrysia), being held together with the latter by five synapomorphies. Although the Exoporia retain almost as many plesiomorphic characters as the Dacnonypha, they have a sister-group relationship with the Monotrysia + Ditrysia, as inferred on the basis of two synapomorphies. The Monotrysia and Ditrysia have a sistergroup relationship, and are the most advanced groups in the Lepidoptera judging from their shared acquisition of many apomorphic characters.