Phylogenetic relationships of elopomorph fishes inferred from mitochondrial ribosomal DNA sequences

The superorder Elopomorpha, a grouping which includes all teleost fishes that possess a specialized leptocephalous larva [true eels (Anguilliformes), gulpers and bobtail snipe eels (Saccopharyngiformes), bonefishes, spiny eels, and halosaurs (Albuliformes, including Notacanthiformes), ladyfishes and tarpons (Elopiformes, including Megalopiformes)] comprises >800 species for which phylogenetic relationships are poorly understood. In the present study, we analyzed mitochondrial DNA sequences in segments of the 12S and 16S rRNA genes in 33 elopomorph taxa encompassing all of the previously proposed orders, and 9 of the 15 currently recognized families of the Anguilliformes, as well as outgroup representatives from the superorders Osteoglossomorpha (nine species) and Clupeomorpha (three species), to develop phylogenetic hypotheses based on distance and parsimony methods. Both methods failed to support the monophyly of the Elopomorpha, casting doubt on the validity of the leptocephalus as an elopomorph synapomorphy. The orders Elopiformes, Albuliformes, and Anguilliformes, however, were resolved as monophyletic assemblages. Parsimony analysis supported the separation of the Anguilliformes into two groups (primitive and advanced) based on the presence of divided versus fused frontal bones. In addition, the molecular data indicated a close affinity of the anguilliform Thalassenchelys coheni (incertae sedis), known only from the leptocephalus, with the family Serrivomeridae. The implications of these data as regards the evolution of the elopomorph assemblage are discussed.     

Molecular phylogeny of elopomorph fishes inferred from mitochondrial 12S ribosomal RNA sequences

Wang, C. H., Kuo, C. H., Mok, H. K. & Lee, S. C. (2003). Molecular phylogeny of elopomorph fishes inferred from mitochondrial 12S ribosomal RNA sequences. — Zoologica Scripta , 32 , 231–241.
Fishes of the superorder Elopomorpha include tenpounders ( Elops ), tarpon ( Megalops ), bonefishes ( Albula ), spiny eels ( Notacanthus ), apodes, and gulper eels; despite highly diversified morphological features, all undergo a leptocephalus larval stage and are thus treated (although with some dissenting views) as monophyletic. Following analysis of 12S rRNA sequences we present results that confirm a monophyletic Elopomorpha clearly separated from Clupeomorpha. Elops and Megalops share a common ancestor and are clustered in a subclade at the bottom of Elopomorpha. Albula and Notacanthus share a common ancestor forming the sister group to Anguilliformes. Saccopharyngiformes is not a sister group of Anguilliformes, as the single species sequenced here is nested deeply within the latter. Neither the suborder Congroidei nor the superfamily Congroidea within Anguilliformes are monophyletic.     

A rod-dominated visual system in leptocephalus larvae of elopomorph fishes (Elopomorpha: Teleostei)

The nature and distributions of photoreceptor cell types were investigated in the retinas of 12 species (5 families) of elopomorph anguilliform leptocephalus larvae. Anti-opsin immunofluorescence, light microscopy and transmission electron microscopy (TEM) were used to assess opsin distribution across the retinas and to associate photoreceptor morphology and opsin content. Retinas of all species were immunoreactive with anti-rhodopsin throughout, while anti-cone opsin immunoreactivity was restricted only to the ventral region of the retina in all specimens. Rod and cone photoreceptors were morphologically indistinguishable at low magnifications; TEM revealed that nearly all photoreceptors had rod-like ultrastructure, with only rare examples of cone-like cells identified in the ventral retina. These results indicate a rhodopsin/rod-dominated retina in leptocephalus larvae of anguilliform eels in the teleost subdivision Elopomorpha, contrasting with the cone-dominated retinas of nearly all other species of teleost larvae. This distinctive developmental pattern shared among elopomorph larvae has important evolutionary and ecological implications, indicating a shared ancestor and/or ecological characteristics that are very different from most other teleost larvae.     

A comprehensive biochemical characterization of settlement stage leptocephalus larvae of bonefish (Albula vulpes)

Little is known about early development of the near-threatened bonefish (Albula vulpes), a member of superorder Elopomorpha. Members of Elopomorpha are partially defined by their synapomorphic leptocephalus larval stage, for which the nutritional requirements are not well understood. Characterizing the nutritional profile, including major nutrients (such as lipids) used for energetic processes, can help to gain a better understanding of the nutritional requirements for leptocephalus larvae. A total of 24 settlement stage A. vulpes leptocephalus larvae were collected at Long Caye Island, Belize. Samples were used to determine various biochemical characteristics including lipid class, fatty acid and glycosaminoglycan compositions. Each of these biochemical components plays a role in early developmental processes such as cellular membrane formation and is crucial for healthy development. Biochemical characteristics of settlement stage A. vulpes leptocephalus are presented in this study for the first time. The dominant lipid classes and fatty acids detected in these samples were consistent with prior studies using closely related species like the Japanese eel, indicating possible similarities in diets at this stage. In the future, similar analyses can be applied to other species that share the leptocephalus life stage to determine if nutritional requirements at this stage of development are unique to this species. The findings in this study will also help to facilitate the establishment of adequate aquaculture systems for captive bonefish, ultimately leading to improved management strategies for wild bonefish habitats.     

Phylogeny and life-history evolution in Carabus (subtribe Carabina: Coleoptera, Carabidae) based on sequences of two nuclear genes

We reconstructed the phylogeny of the holarctic carabid subtribe Carabina (= Carabus s . l. ; Coleoptera, family Carabidae, supertribe Carabitae, tribe Carabini) using sequence data from two nuclear DNA loci: wingless ( Wg ) and phosphoenolpyruvate carboxykinase ( PepCK ). The analysis of the combined data resulted in a well-resolved tree, although Wg and PepCK had partially conflicting phylogenetic signals. The tree topology did not support the reciprocal monophyly of some previously proposed major divisions, whereas all but one of eight other previously proposed subdivisions were recovered as monophyletic clades; the exception was paraphyletic. When two key life-history traits, seasonal life cycle and larval diet, were mapped onto the combined tree, spring breeding (with no larval overwintering) and insectivorous were ancestral traits. Malacophagy has apparently evolved at least twice: once in a small basal group (ten species) and again in a large derived group ( c . 340 species) that accounts for 42% of the species of Carabina. A third type of larva, earthworm feeders, appeared in two related, derived clades and represented moderate species diversity (12%). From the ancestral spring-breeder type with no larval overwintering, autumn-breeder types with larval overwintering apparently evolved repeatedly in insectivorous and malacophagous species, but not in earthworm feeders. Therefore, the extant diversity of the Carabina depends on the high rate of differentiation in the most derived group of malacophagous species.  © 2004 The Linnean Society of London, Biological Journal of the Linnean Society , 2004, 81 , 135–149.     

Evolution of the deep-sea gulper eel mitochondrial genomes: large-scale gene rearrangements originated within the eels

Recent studies have demonstrated that deviations from the typical vertebrate mitochondrial gene order are more frequent than initially thought. Such deviations, however, are minor, with inversions and/or translocations of a few genes being involved and tandem duplication of the gene regions followed by deletions of genes having been invoked as mechanisms originating in such novel gene order. During the course of molecular phylogenetic studies on the Elopomorpha (eels and their allies), we found that mitochondrial genomes (mitogenomes) from the two deep-sea gulper eels, Eurypharynx pelecanoides (Eurypharyngidae) and Saccopharynx lavenbergi (Saccopharyngidae), exhibit an identical gene order which greatly differs from that of any other vertebrates. Phylogenetic analysis using the mitogenomic data from 59 species of fish not only confirmed a single origin of such a gene order with confidence but also indicated that it had been derived from the typical vertebrate gene order. Detailed comparisons of the gulper eel gene order with that of typical vertebrates suggested that occurrence of a single step, large-scale duplication of gene region extending >12 kb, followed by deletions of genes in a common ancestor of the two species, most parsimoniously accounts for this unusual gene arrangement.     

Basal teleosts and the question of elopomorph monophyly. Morphological and molecular approaches

The methodology used by previous authors to resolve the relationships of the elopomorphan taxa is criticized. The morphological characters that have been proposed to support the monophyly of the Elopomorpha are reviewed and it is shown that most of them are weak. A new hypothesis of relationships is proposed on the basis of nucleotidic sequences of ribosomal RNA 18S, 16S and 12S. In order to really test all the possible relationships, the monophyly of the Elopomorpha was not considered a priori. The tree was rooted on Amia calva and Lepisosteus osseus and the ingroup taxa sampling was subsequently increased. The obtained topology shows that the Elopomorpha is a non-monophyletic taxon. Elopiforms, anguilliforms, albuliforms and notacanthiforms are considered here as four monophyletic, incertae sedis taxa among basal teleosts.     

Identification,structural analysis and function of hyaluronan in developing fish larvae (leptocephali)

Hyaluronan (HA) has been identified as the principal glycosaminoglycan (CAG) in the highly hydrated, extracellular body matrix of the larval stage (leptocephalus) of seven species of true eels (Teleostei: Elopomorpha: Anguilliformes) and the ladyfish Elops saurus (Elopiformes), and was found as a minor GAG component in the bonefish Albula sp. (Albuliformes). Identification was based on: (1) HPLC separation of unsaturated disaccharides derived from chondroitinase ABC digests of whole-body GAG extracts; (2) 1H NMR analyses of native GAG polymers; and (3) degradation of GAG extracts by Streptomyces hyaluronan lyase. The unsaturated disaccharide 2-acetamido-2-deoxy-3-O-(beta-D-gluco-4-enepyranosyluronic acid)-D-glucose (DeltaDi-HA) accounted for 92.4-99.8% of the total disaccharides in chondroitinase digests. Trace amounts of unsaturated disaccharides of chondroitin sulfate were also present. Two-dimensional gCOSY spectra of the native HA polymer were similar for all species. Proton assignments for the HA disaccharide repeat (GlcAbeta1-3GlcNAcbeta1-4) in D(2)O, based on gCOSY, DQF-COSY and TOCSY analyses for the eel Ahlia egmontis, were concordant with published chemical shifts for HA oligosaccharides. In addition to its presumed role in maintaining the structural integrity and hydration of the gelatinous body of the leptocephalus, HA is postulated to function as a storage polysaccharide in those species in which it is the predominant GAG.     

Phylogenetic relationships of Nembrothinae (Mollusca: Doridacea: Polyceridae) inferred from morphology and mitochondrial DNA

Within the Polyceridae, Nembrothinae includes some of the most striking and conspicuous sea slugs known, although several features of their biology and phylogenetic relationships remain unknown. This paper reports a phylogenetic analysis based on partial sequences of two mitochondrial genes (cytochrome c oxidase subunit I and 16S rRNA) and morphology for most species included in Nembrothinae. Our phylogenetic reconstructions using both molecular and combined morphological and molecular data support the taxonomic splitting of Nembrothinae into several taxa. Excluding one species (Tambja tentaculata), the monophyly of Roboastra was supported by all the phylogenetic analyses of the combined molecular data. Nembrotha was monophyletic both in the morphological and molecular analyses, always with high support. However, Tambja was recovered as para- or polyphyletic, depending on the analysis performed. Our study also rejects the monophyly of "phanerobranch" dorids based on molecular data.     

Phylogenetic position of tetraodontiform fishes within the higher teleosts: Bayesian inferences based on 44 whole mitochondrial genome sequences

Tetraodontiformes includes approximately 350 species assigned to nine families, sharing several reduced morphological features of higher teleosts. The order has been accepted as a monophyletic group by many authors, although several alternative hypotheses exist regarding its phylogenetic position within the higher teleosts. To date, acanthuroids, zeiforms, and lophiiforms have been proposed as sister-groups of the tetraodontiforms. The monophyly and sister-group status was investigated using whole mitochondrial genome (mitogenome) sequences from 44 purposefully-chosen species (26 sequences newly-determined during the study) that fully represent the major tetraodontiform lineages plus all the groups that have been hypothesized as being close relatives. Partitioned Bayesian analyses were conducted with the three datasets that comprised concatenated nucleotide sequences from 13 protein-coding genes (with and without, or with RY-coding, 3rd codon positions), plus 22 transfer RNA and two ribosomal RNA genes. The resultant trees were well resolved and largely congruent, with most internal branches being supported by high posterior probabilities. Mitogenomic data strongly supported the monophyly of tetraodontiform fishes, placing them as a sister-group of either Lophiiformes plus Caproidei or Caproidei only. The sister-group relationship between Acanthuroidei and Tetraodontiformes was statistically rejected using Bayes factors. These results were confirmed by a reanalysis of the previously published nuclear RAG1 gene sequences using the Bayesian method. Within the Tetraodontiformes, however, monophylies of the three superfamilies were not recovered and further taxonomic sampling and subsequent efforts should clarify these relationships.     

A mitogenomic perspective on the basal teleostean phylogeny: resolving higher-level relationships with longer DNA sequences

A recent study demonstrated that mitochondrial genomic (mitogenomic) data comprising nucleotide sequences from the concatenated protein-coding (no 3rd codon positions) plus transfer RNA (stem regions only) genes reproduced the expected phylogeny of teleosts with high statistical support. We reexamined the interrelationships of the five major, basal teleostean lineages (Osteoglossomorpha, Elopomorpha, Clupeomorpha, Ostariophysi, and Protacanthopterygii; given various rankings) using mitogenomic data for which five alternative phylogenetic hypotheses have been previously proposed on the basis of both morphological and molecular analyses. In addition to previously determined complete mitochondrial DNA (mtDNA) sequences from eight basal teleosts and two outgroups, we determined the complete mtDNA sequences (excluding a portion of the control region) for two, purposefully chosen species of Osteoglossomorpha (Osteoglossum bicirrhosum and Pantodon buchholzi), and the data were subjected to maximumparsimony and maximum-likelihood analyses. The resultant tree topologies from the two methods were congruent, although they differed from any of the previously proposed hypotheses. Furthermore, the mitogenomic data confidently rejected all of these hypotheses with high statistical significance.     

A molecular phylogenetic framework for the evolution of parasitic strategies in cymothoid isopods (Crustacea)

The parasitic isopods belonging to the family Cymothoidae attach under the scales, in the gills or on the tongue of their fish hosts, exhibiting distinctive life-histories and morphological modifications. According to conventional views, the three parasitic types (scale-, gill-, and mouth-dwellers) correspond to three distinct lineages. In this study, we have used fragments of two mitochondrial genes (large ribosomal DNA subunit, 16S rRNA, and cytochrome oxidase I) and two species for each of the three parasitic habits to present a preliminary hypothesis on the evolutionary history of the family. Our molecular data support the monophyly of the family but suggest that – contrary to what was previously believed – the more specialized mouth- and gill-inhabiting species are not necessarily derived from scale-dwelling ones.     

Molecular phylogeny and larval morphological diversity of the lanternfish genus Hygophum (Teleostei: Myctophidae)

Larvae of the deep-sea lanternfish genus Hygophum (Myctophidae) exhibit a remarkable morphological diversity that is quite unexpected, considering their homogeneous adult morphology. In an attempt to elucidate the evolutionary patterns of such larval morphological diversity, nucleotide sequences of a portion of the mitochondrially encoded 16S ribosomal RNA gene were determined for seven Hygophum species and three outgroup taxa. Secondary structure-based alignment resulted in a character matrix consisting of 1172 bp of unambiguously aligned sequences, which were subjected to phylogenetic analyses using maximum-parsimony, maximum-likelihood, and neighbor-joining methods. The resultant tree topologies from the three methods were congruent, with most nodes, including that of the genus Hygophum, being strongly supported by various tree statistics. The most parsimonious reconstruction of the three previously recognized, distinct larval morphs onto the molecular phylogeny revealed that one of the morphs had originated as the common ancestor of the genus, the other two having diversified separately in two subsequent major clades. The patterns of such diversification are discussed in terms of the unusual larval eye morphology and geographic distribution.     

A phylogeny of the Australian Sphenomorphus group (Scincidae: Squamata) and the phylogenetic placement of the crocodile skinks (Tribolonotus): Bayesian approaches to assessing congruence and obtaining confidence in maximum likelihood inferred relationships

Australian scincid lizards are a diverse squamate assemblage ( approximately 385 species), divided among three major clades (Egernia, Eugongylus, and Sphenomorphus groups). The Sphenomorphus group is the largest, comprising 61% of the Australian scincid fauna. Phylogenetic relationships within the Australian Sphenomorphus group and the phylogenetic placement of Tribolonotus are inferred using mtDNA (12S and 16S rRNA genes, ND4 protein-coding gene, and associated tRNA genes; 2185bp total). These data were analyzed separately (structural RNA vs protein-coding partitions) and combined using maximum likelihood. Confidence in inferred clades was assessed using non-parametric bootstrapping and Bayesian analysis. Analysis of the combined data strongly supports Sphenomorphus group (as well as the Australian subgroup) monophyly. Notoscincus is strongly placed as the sister taxon of the remaining Australian Sphenomorphus group taxa, with this more exclusive clade being divided into two major groups (one restricted to mesic eastern Australia and the other continent wide). The speciose Australian "Eulamprus" and "Glaphyromorphus" are both polyphyletic. All remaining non-Sphenomorphus group lygosomine skinks strongly form a clade, with Tribolonotus placed as the sister taxon of the Australian Egernia group.     

Towards an explanation of the developmental strategy in leptocephalous larvae of marine teleost fishes

Synopsis Various observations on the morphology, physiology and biochemistry of leptocephalous larvae of different groups of marine teleost fishes have been brought together in order to arrive at a model which attempts to explain the ‘leptocephalous strategy’ of larval development. The observation that basic similarities are found in the developmental pattern of all groups of fishes with a leptocephalus (Superorder: Elopomorpha) forms the basis for proposing a common strategy within the superorder. Circumstantial evidence suggesting that premetamorphic (Phase I) larvae obtain a significant fraction of their nutritional needs by absorbing dissolved organic matter across surface epithelia has been reviewed. It is suggested that this might occur via a Na⁺-mediated transport system similar to that seen in various marine invertebrates. Breakdown of the gelatinous matrix formed during Phase I is assumed to provide the nutrients required for the metamorphic larvae (Phase II). This strategy is then contrasted with the more ‘typical’ form of larval development in marine teleosts and shown to differ in several basic respects.     

Molecular phylogeny based on mitochondrial genes and evolution of host plant use in the long-horned beetle tribe Lamiini (Coleoptera: Cerambycidae) in Japan

The molecular phylogeny of the long-horned beetle tribe Lamiini Mulsant (Coleoptera: Cerambycidae) in Japan (12 genera, 25 species, 3 additional subspecies) was determined based on mitochondrial 16S rRNA and cytochrome oxydase subunit I. The monophyly of the tribe Lamiini was supported, whereas that of the genus Acalolepta Pascoe was unclear. Evolution of host plant use in Lamiini was estimated using the molecular phylogeny. For adult and larval host plant kind-and-condition, the most ancestral state was for weakened to dead broad-leaved trees, whereas derived states favored conifers, healthy broad-leaved trees, and herbs. For adult and larval host range, the most ancestral state was polyphagy, whereas oligophagy and monophagy were derived. Evolution of hosts' idiosyncrasy and that of the insects' host range were related in many lineages. Our results partly support the hypothesis that habitation in living trees requires dietary specialization in phytophagous insects.     

Mitochondrial and nuclear markers support the monophyly of Dolichopodidae and suggest a rapid origin of the subfamilies (Diptera: Empidoidea)

Abstract. The Dolichopodidae is a species‐rich dipteran group with almost 7000 described species. The monophyly of the subfamilies and their relationships remain largely unknown because the polarities of key morphological characters are unclear and molecular data are available only for 9 of the 19 proposed subfamilies. Here we test whether molecular data from two nuclear (18S, 28S) and four mitochondrial (12S, 16S, Cytb, COI) genes can resolve the higher‐level relationships within the family. Our study is based on 76 Oriental species from 12 dolichopodid subfamilies and uses eight species of Empididae and Hybotidae as outgroups. Parsimony and likelihood analyses confirm the monophyly of the Dolichopodidae, as well as the monophyly of five of the ten subfamilies represented by more than two species [Sympycninae, Sciapodinae, Dolichopodinae, Hydrophorinae (excluding tribe Aphrosylini), Neurigoninae]. There is strong support for restoring the tribe Aphrosylini as a separate subfamily Aphrosylinae. The monophyly of Medeterinae, Peloropeodinae and Diaphorinae is dependent on which tree reconstruction technique is used, how indels are coded, and whether the fast‐evolving sites are excluded. Overall, we find that our sample of Oriental species is largely compatible with the subfamily concepts that were developed for the northern temperate fauna. However, our data provide little support for relationships between the subfamilies. Branch lengths, saturation, and distance plots suggest that this is probably the result of the rapid origin of dolichopodid subfamilies over a relatively short time. We find that genera that are difficult to place into subfamilies based on morphological characters are generally also difficult to place using molecular data. We predict that a dense, balanced taxon sample and protein‐encoding nuclear genes will be needed to resolve the higher‐level relationships in the Dolichopodidae.     

Testing the monophyly of the New Zealand and Australian endemic family Conoesucidae Ross based on combined molecular and morphological data (Insecta: Trichoptera: Sericostomatoidea)

Conoesucidae (Trichoptera, Insecta) are restricted to SE Australia, Tasmania and New Zealand. The family includes 42 described species in 12 genera, and each genus is endemic to either New Zealand or Australia. Although monophyly has been previously assumed, no morphological characters have been proposed to represent synapomorphies for the group. We collected molecular data from two mitochondrial genes (16S and cytochrome oxidase I), one nuclear gene (elongation factor 1-α) (2237–2277 bp in total), and 12 morphological characters to produce the first phylogeny of the family. We combined the molecular and morphological characters and performed both a maximum parsimony analysis and a Bayesian analysis to test the monophyly of the family, and to hypothesize the phylogeny among its genera. The parsimony analysis revealed a single most parsimonious tree with Conoesucidae being a monophyletic taxon and sistergroup to the Calocidae. The Bayesian inference produced a distribution of trees, the consensus of which is supported with posterior probabilities of 100% for 15 out of 22 possible ingroup clades including the most basal branch of the family, indicating strong support for a monophyletic Conoesucidae. The most parsimonious tree and the tree from the Bayesian analysis were identical except that the ingroup genus Pycnocentria changed position by jumping to a neighbouring clade. Based on the assumption that the ancestral conoesucid species was present on both New Zealand and Australia, a biogeographical analysis using the dispersal-vicariance criteria demonstrated that one or two (depending on which of the two phylogenetic reconstructions were applied) sympatric speciation events took place on New Zealand prior to a single, late dispersal from New Zealand to Australia.     

Phylogeny of the genera Entamoeba and Endolimax as deduced from small-subunit ribosomal RNA sequences

We sequenced small-subunit ribosomal RNA genes (16S-like rDNAs) of 10 species belonging to the genera Entamoeba and Endolimax. This study was undertaken to (1) resolve the relationships among the major lineages of Entamoeba previously identified by riboprinting; (2) examine the validity of grouping the genera Entamoeba and Endolimax in the same family, the Entamoebidae; and (3) examine how different models of nucleotide evolution influence the position of Entamoeba in eukaryotic phylogenetic reconstructions. The results obtained with distance, parsimony, and maximum-likelihood analyses support monophyly of the genus Entamoeba and are largely in accord with riboprinting results. Species of Entamoeba producing cysts with the same number of nuclei from monophyletic groups. The most basal Entamoeba species are those that produce cysts with eight nuclei, while the group producing four-nucleated cysts is most derived. Most phylogenetic reconstructions support monophyly of the Entamoebidae. In maximum-likelihood and parsimony analyses, Endolimax is a sister taxon to Entamoeba, while in some distance analyses, it represents a separate lineage. The secondary loss of mitochondria and other organelles from these genera is confirmed by their relatively late divergence in eukaryotic 16S-like rDNA phylogenies. Finally, we show that the positions of some (fast-evolving) eukaryotic lineages are uncertain in trees constructed with models that make corrections for among-site rate variation.