From capsules to nutlets—phylogenetic relationships in the Boraginales

Multiple family‐level subdivisions of Boraginales have been proposed in the past. The relationships of several constituent genera have been enigmatic, including Codon (Codonaceae), Hoplestigma (Hoplestigmataceae), Pholisma (Lennoaceae), Vahlia (Vahliaceae), and Wellstedia (Wellstediaceae), all of which are included in the present study. We present a molecular analysis with four chloroplast loci, including 89 ingroup taxa and a broad outgroup sampling in the asterids. The genus Vahlia is excluded from Boraginales and appears to represent an early branching lineage of Lamiales. The study provides a well supported topology for the relationships within Boraginales, including all of the genera with previously unclear relationships. Within Boraginales, two major clades are recognized, with “herbaceaous” Boraginales I resolved as [Codonaceae,[Wellstediaceae,[Boraginaceae]]] and “woody” Boraginales II resolved as [Hydrophyllaceae I,[Hydrophyllaceae II,[Heliotropiaceae,[Cordiaceae,[Ehretiaceae,Lennoaceae]]]]. A close relationship between Ehretiaceae and Lennoaceae is well supported, but the exact placement of Lennoaceae remains unresolved. The Cordiaceae lineage includes the monotypic genus Coldenia and the aberrant western and central African genus Hoplestigma. Woody Boraginales II are retrieved in two highly supported clades. Hydrophyllaceae are retrieved in two separate clades, but with poor support. There appear to be clear morphological progressions in vegetative, floral, and fruit morphology in both major Boraginales lineages. Thus capsular fruits are found in the first branching lineages of both clades, whereas reduced seed numbers in indehiscent fruits predominate in the more derived phylogenetic positions. Based on these results, we advocate the recognition of eight morphologically well defined clades in the order, namely Boraginaceae s.str., Codonaceae, Cordiaceae (incl. Coldenia and Hoplestigmataceae), Ehretiaceae (incl. Lennoaceae), Heliotropiaceae, Hydrophyllaceae I and Hydrophyllaceae II, and Wellstediaceae.     

Transfer cells in the seeds of Boraginales

The presence of transfer cells (TCs) in the seeds of Boraginales (Boraginaceae s.s. , Hydrophyllaceae, Heliotropiaceae, Ehretiaceae, Cordiaceae and Lennoaceae) has been reported but has not hitherto been studied systematically. This study, surveying the seed anatomy of 50 species of Boraginales, demonstrates that in Heliotropiaceae, Cordiaceae, Ehretiaceae and Lennoaceae, TCs are found in an uninterrupted course from the placenta via the funicle to the seed coat. These families are characterized by indehiscent fruits with a protective endocarp. The TCs may act as a sponge, thus promoting rapid germination when sufficient water is available. In Hydrophyllaceae, which have capsular fruits, TCs are often found but have a different structure and are restricted to the seed coat. Boraginaceae s.s. on the other hand are characterized by a complete absence of TCs in their seeds. The presence of TCs in seeds is considered as a synapomorphic trait and appears to be phylogenetically informative.  © 2002 The Linnean Society of London, Botanical Journal of the Linnean Society , 2002, 140 , 155−164.     

Floral Ontogeny in Bourreria (Ehretiaceae, Boraginales)

Gynoecium and fruit ontogeny is studied in eight species of Bourreria (Ehretiaceae, Boraginales). The internal architecture of the bicarpellate ovary results from the development of several secondary septs, i.e., apical, basal, and false septs. Flower and fruit morphology provide additional characters for phylogenetic analyses. Apomorphies of monophyletic Bourreria are the valvate calyx lobes, an extensive disc, and an additional sterile chamber in each endocarpid (i.e., fruit part). The development of transfer cells and endosperm haustoria confirm the systematic placement of Bourreria in the Primarily Woody Boraginales (i.e., Heliotropiaceae, Cordiaceae, and Ehretiaceae including Lennoaceae). However, the precise systematic position of Bourreria within Ehretiaceae cannot be resolved on the basis of the morphological data provided here.     

Molecular phylogenetics of the tribeInuleae s. str.(Asteraceae), based on ITS sequences of nuclear ribosomal DNA

The sequences of the internal transcribed spacer (ITS) region of 18S–26S nrDNA for a sample of 16 taxa from theInuleae s. str. and two outgroup taxa are analysed cladistically with PAUP. A consensus tree of the four most parsimonious cladograms is presented. Three different tests of cladogram stability are conducted (Bremer support, parsimony jackknifing and bootstrapping); all tests indicate a high degree of support for the basal nodes of the tree. The ITS phylogeny of the tribe is compared with previous hypotheses based on morphological data. The position ofAnisopappus as sister group to the rest of the tribe is supported by the molecular data, but the proposed subdivision ofInuleae s. str. into a paleate grade group and an epaleate clade is not. The interpretation of the character evolution of, e.g. receptacular paleae and pappus features within the tribe is discussed.     

POLLEN MORPHOLOGY OF THE LENNOACEAE

Drugg , Warren S. (California Res. Corp., La Habra.) Pollen morphology of the Lennoaceae. Amer. Jour. Bot. 49(10): 1027–1032. Illus. 1962.—The family Lennoaceae contains 3 genera: Pholisma, Lennoa, and Ammobroma. The pollen of Pholisma is 4-colporate with less common 3- and 5-colporate grains. Lennoa pollen is 3-colporate with rare 4-colporate examples. All Ammobroma pollen is 3-colporate. Pollen of both Lennoa and Ammobroma exhibits sexine thinning in the mesocolpia with resultant depressions. This feature is lacking in Pholisma. Sculpture is reticulate-simplibaculate on pollen of Lennoa and Pholisma, and reticulate-duplibaculate on pollen of Ammobroma. Pollen morphology supports placement of Lennoaceae in the Polemoniales near the Boraginaceae and Hydrophyllaceae.     

Phylogeny and systematics of the genus Lophozia s. str. (Dumort.) Dumort. (Hepaticae) and related taxa from nuclear ITS1-2 and chloroplast trnL-F sequences

Nuclear ITS1-2 and chloroplast trnL-F were sequenced for 21 taxa of Lophozia s. str., two species of Protolophozia, five species of Schistochilopsis, three species of Barbilophozia and Obtusifolium obtusum. The topologies of phylogenetic trees for 49 taxa constructed from combined sequences of these regions by maximum parsimony, maximum likelihood and Bayesian methods are similar. The species of Lophozia s. str., excluding Lophozia sudetica, combine into two main clades and these contradict subdivisions of Lophozia s. str. based on morphology. The species status of Lophozia lantratoviae is confirmed, whereas Lophozia austro-sibirica is almost identical to Lophozia ventricosa var. guttulata. The genus Schistochilopsis is paraphyletic and occupies basal position to Lophozia s. str., while O. obtusum is clearly separated from Schistochilopsis. A low level of divergence was found between L. sudetica and Protolophozia debiliformes, which are closer to Barbilophozia than to Lophozia s. str. Molecular divergence between geographically remote populations of L. sudetica, Lophozia silvicoloides and Protolophozia debiliformis are low as opposed to those of Lophozia polaris, Lophozia pellucida or Lophozia excisa. Consideration of the trnL intron P8 region indels alone can adequately assign some clades revealed by tree building. A consensus secondary structure of the trnL intron P8 region could not be inferred for taxa studied mainly due to high sequence length diversity originated from deletions.     

Generative ontogeny in Tiquilia (Ehretiaceae: Boraginales) and phylogenetic implications

Tiquilia is very different from the other members of the Ehretiaceae (Boraginales) in many aspects of morphology and ecology. Because detailed knowledge about flower and fruit traits is necessary to reliably infer character evolution of and within Tiquilia, we investigated flower to fruit ontogeny in eight species of Tiquilia using light and electron microscopy. Tiquilia accumulated a number of autapomorphies such as the prostrate growth form, the lack of lateral and ventral bundles in the gynoecium, and the formation of nutlet‐like mericarpids as dispersal units instead of more or less succulent drupes. The internal architecture of the superior bicarpellate ovary resulted from the development of several secondary septa including apical, basal and false septa, as it has been reported also from other Boraginales. However, no character found in Tiquilia can be regarded as synapomorphic with any other taxon of the Ehretiaceae. © 2014 The Linnean Society of London, Biological Journal of the Linnean Society, 2014, 112 , 520–534.     

Molecular systematics of Boraginaceae tribe Boragineae based on ITS1 and trnL sequences, with special reference to Anchusa s.l

BACKGROUND AND AIMS: Boragineae is one of the main tribes of Boraginaceae, but delimitation and intergeneric classification of this group are unclear and have not yet been studied using DNA sequences. In particular, phylogenetic relationships in Anchusa s.l. still need to be elucidated in order to assess its taxonomic boundaries with respect to the controversial segregate genera Hormuzakia, Gastrocotyle, Phyllocara and Cynoglottis. METHODS: Phylogenetic relationships among 51 taxa of tribe Boragineae were investigated by comparative sequencing of the trnL(UAA) intron of the plastid genome and of the ITS1 region of the nuclear ribosomal DNA. Exemplar taxa from 16 genera of Boragineae and all subgenera of Anchusa s.l. were included, along with two selected outgroups from tribes Lithospermeae and Cynoglosseae. KEY RESULTS: Phylogenies generated by maximum parsimony and combined ITS1-trnL sequences support the monophyly of the tribe and a split into two clades, Pentaglottis and the remainder of Boragineae. The latter contains two large monophyletic groups. The first consists of three moderately to well-supported branches, Borago-Symphytum, Pulmonaria-Nonea and Brunnera. In the Pulmonaria-Nonea subclade, the rare endemic Paraskevia cesatiana is sister to Pulmonaria, and Nonea appears to be paraphyletic with respect to Elizaldia. The second main group corresponds to the well-supported clade of Anchusa s.l., with the megaphyllic, polyploid herb Trachystemon orientalis as sister taxon, although with low support. Anchusa s.l. is highly paraphyletic to its segregate genera and falls into four subclades: (1) Phyllocara, Hormuzakia, Anchusa subgenus Buglossum and A. subgenus Buglossoides; (2) Gastrocotyle; (3) A. subgenus Buglossellum and Cynoglottis; and (4) A. subgenus Anchusa, Lycopsis and Anchusella. All species of Anchusa subg. Anchusa, including the South African A. capensis, are included in a single unresolved clade. Anchusa subgenus Limbata is also included here despite marked divergence in floral morphology. The low nucleotide variation of ITS1 suggests a recent partly adaptive radiation within this group. CONCLUSIONS: Molecular data show that nine of the usually accepted genera of the Boragineae consisting of two or more species are monophyletic: Anchusella, Borago, Brunnera, Cynoglottis, Gastrocotyle, Hormuzakia, Nonea, Pulmonaria and Symphytum. In addition, the tribe includes the four monotypic genera Paraskevia, Pentaglottis, Phyllocara and Trachystemon. The morphologically well-characterized segregate genera in Anchusa s.l. are all confirmed by DNA sequences and should be definitively accepted. Most of the traditionally recognized subgenera of Anchusa are also supported as monophyletic groups by both nuclear and plastid sequence data. In order to bring taxonomy in line with phylogeny, the institution of new, independent generic entities for subgenera Buglossum, Buglossellum and Buglossoides and a narrower but more natural concept of Anchusa are advocated.     

First fossil record of transfer cells in angiosperms

Transfer cells are specialized plant cells that optimize short-distance transport by an extension of the interior surface of the cell walls. Using scanning electron microscopy (SEM), we found transfer cells in the fossil seed coat of Ehretia clausentia (Ehretiaceae, Boraginales) from the London Clay flora (Lower Eocene). This is the first fossil record of transfer cells in angiosperms.     

New Boraginales from tropical America 8: Nomenclatural notes on Varronia (Cordiaceae: Boraginales)

A review of the species of the neotropical genus Varronia (Cordiaceae: Boraginales), for several floristic projects and the preparation of a treatment for the Online World Flora, reveals several nomenclatural issues, which include four new combinations and a nomen novum for one additional species.     

Phylogeny and taxonomic revision of plastid-containing euglenophytes based on SSU rDNA sequence comparisons and synapomorphic signatures in the SSU rRNA secondary structure

Sequence comparisons and a revised classification of the Euglenophyceae were based on 92 new SSU rDNA sequences obtained from strains of Euglena, Astasia, Phacus, Trachelomonas, Colacium, Cryptoglena, Lepocinclis, Eutreptia, Eutreptiella and Tetreutreptia. Sequence data also provided molecular signatures for taxa from genus to class level in the SSU rRNA secondary structure, revealed by a novel approach (search for non-homoplasious synapomorphies) and used for taxonomic diagnoses. Photosynthetic euglenoids and secondary heterotrophs formed a clade, designated as Euglenophyceae (emend.) with two orders: Euglenales and Eutreptiales. The mostly marine Eutreptiales (Eutreptia, Eutreptiella; not Distigma) comprised taxa with two or four emergent flagella (the quadriflagellate Tetreutreptia was integrated within Eutreptiella). The Euglenales (freshwater genera with < or = one emergent flagellum) formed nine clades and two individual branches (single strains); however, only two clades were congruent with traditional genera: Trachelomonas (incl. Strombomonas) and Colacium. Euglena was polyphyletic and diverged into four independent clades (intermixed with Astasia, Khawkinea and Lepocinclis) and two individual branches (e.g. E. polymorpha). Phacus was also subdivided into Phacus s. str. and two combined lineages (mixed with Lepocinclis spp. or Cryptoglena). In consequence, Euglena (s. str.), Phacus and other genera were emended and one lineage (mixed Phacus/Lepocinclis-clade) was recognized as the previously neglected genus Monomorphina Mereschkowsky (1877). The sister clade of Phacus s. str. (mixed Euglena/Lepocinclis-clade) was identified as Lepocinclis Perty (emended).     

Secondary structure models of the nuclear internal transcribed spacer regions and 5.8S rRNA in Calciodinelloideae (Peridiniaceae) and other dinoflagellates

Secondary structure models of the 5.8S rRNA and both internal transcribed spacers (ITS1 and ITS2) are proposed for Calciodinelloideae (Peridiniaceae) and are also plausible for other dinoflagellates. The secondary structure of the 5.8S rRNA corresponds to previously developed models, with two internal paired regions and at least one 5.8S rRNA–28S rRNA interaction. A general secondary structure model of ITS1 for Calciodinelloideae (and other dinoflagellates), consisting of an open multibranch loop with three major helices, is proposed. The homology of these paired regions with those found in other taxa, published in previous studies (e.g. yeast, green algae and Platyhelmithes) remains to be determined. Finally, a general secondary structure model of ITS2 for Calciodinelloideae (and other dinoflagellates) is reconstructed. Based on the 5.8S rRNA–28S rRNA interaction, it consists of a closed multibranch loop, with four major helices. At least helix III and IV have homology with paired regions found in other eukaryotic taxa (e.g. yeast, green algae and vertebrates). Since the secondary structures of both ITS regions are more conserved than the nucleotide sequences, their analysis helps in understanding molecular evolution and increases the number of structural characters. Thus, the structure models developed in this study may be generally useful for future phylogenetic analyses.     

Phylogeny and classification of the Grimmiaceae/Ptychomitriaceae complex (Bryophyta) inferred from cpDNA

Phylogenetic relationships within the Grimmiaceae/Ptychomitriaceae were studied using a plastid tRNA cluster, including four tRNAs (trnS, trnT, trnL, trnF), a fast evolving gene (rps4), four spacers separating the coding regions, as well as one group I intron. Secondary structure analyses of the spacers as well as the trnL intron P8 domain identified several homoplastic inversions. Tracing the structural evolution of P8 we were able to identify lineage specific modifications that are mainly explained by inversions often in combination with large indel events. Phylogenetic analyses using maximum parsimony, maximum likelihood, and Bayesian methods indicate that Jaffueliobryum and Indusiella are closely related to Ptychomitrium and form the Ptychomitriaceae s. str. As Campylostelium is neither resolved within Ptychomitriaceae s. str. nor Grimmiaceae s. str., we prefer to treat it in its own family, Campylosteliaceae De Not. The systematic position of Glyphomitrium, as also found by other authors, should be considered in a broader analysis of haplolepidous mosses as our analyses indicate that it is not part of Campylosteliaceae, Grimmiaceae, or Ptychomitriaceae. Within Grimmiaceae s. str., Racomitrium is recognized as a monophyletic group sister to a clade including Dryptodon, Grimmia, and Schistidium. Coscinodon species appear disperse in Grimmia s. str. next to species sharing the same gametophyte morphology, and thus the genus is synonymized with Grimmia. Finally, Schistidium is resolved monophyletic with high statistical support, and seems to represent a rapidly evolving group of species. Our results are not fully congruent with recently published treatments splitting Grimmiaceae in a fairly high number of genera, neither with a comprehensive Grimmia including Dryptodon and Grimmia s. str.     

Molecular phylogenetics and diagnosis of Anisakis, Pseudoterranova, and Contracaecum from northern Pacific marine mammals

Individual specimens of Anisakis, Pseudoterranova, and Contracaecum collected from marine mammals inhabiting northern Pacific waters were used for comparative diagnostic and molecular phylogenetic analyses. Forty-eight new sequences were obtained for this study of 14 Anisakis taxa, 8 Pseudoterranova taxa, 4 Contracaecum taxa, and 4 outgroup species. Partial 28S (LSU) and complete internal transcribed spacer (ITS-1, 5.8S, ITS-2) ribosomal DNA was amplified by the polymerase chain reaction and sequenced. Sequences of ITS indicated that Pseudoterranova specimens from Zalophus californianus (California sea lion), Mirounga angustirostris (northern elephant seal), Phoca vitulina (harbor seal), Enhydra lutris (sea otter), and Eumetopias jubatus (Steller's sea lion) exactly matched P. decipiens s. str., extending the host and geographic range of this species. Anisakis from northern Pacific marine mammals were most closely related to members of the A. simplex species complex. Comparison of Anisakis ITS sequences diagnosed the presence of A. simplex C in 2 M. angustirostris hosts, which is a new host record. Anisakis specimens from Phocoena phocoena (harbor porpoise), Lissodelphis borealis (Pacific rightwhale porpoise), and E. jubatus included 3 ITS sequences that did not match any known species. Contracaecum adults obtained from Z. californianus were most closely related to C. ogmorhini s.l. and C. rudolphii, but ITS sequences of these Contracaecum specimens did not match C. ogmorhini s. str. or C. margolisi. These novel Anisakis and Contracaecum ITS sequences may represent previously uncharacterized species. Phylogenetic analysis of LSU sequences revealed strong support for the monophyly of Anisakinae, Contracaecum plus Phocascaris, Pseudoterranova, and Anisakis. Phylogenetic trees inferred from ITS sequences yielded robustly supported relationships for Pseudoterranova and Anisakis species that are primarily consistent with previously published phenograms based on multilocus electrophoretic data.     

Analysis of the internal transcribed spacer 2 (ITS2) region of scuticociliates and related taxa (Ciliophora, Oligohymenophorea) to infer their evolution and phylogeny

The ITS2 (ITS--internal transcribed spacer) region of the rDNA in 11 representative scuticociliates and two ambiguously related genera was analyzed. In common with other eukaryotes, the putative ITS2 folding pattern consists of a closed loop with four helices supported by minimum free energy and compensatory base changes (CBCs), although two of these helices are variable and sometimes absent. Three topologies were obtained on the basis of traditional primary sequence analysis, "string" strategy of secondary structure and analysis of the combined data. It was found that the secondary structure information could help to improve alignment and utilize appropriately phylogenetic strategies. The proposed phylogenies, though differing between sequence- and structure-based results, provide consistent support for high-level clades: the systematically questionable genera Dexiotrichides and Cardiostomatella always cluster together in a clade basal to the scuticociliates s.s., whereas Pleuronema branches from other uronematids at a deep level, and is hence a divergent taxon. Within the well-supported monophyletic philasterids, a sister relationship exists between Orchitophrya and Mesanophrys, while Uronema shows a close relationship with the group including Paranophrys and Parauronema. The positions of Metanophrys, Pseudocohnilembus and Anophryoides among the philasterids remain poorly resolved. Our findings firmly support the proposed evolutionary scenario inferred previously both from morphological and molecular data.