Phylogenetic analysis of Lappula Moench (Boraginaceae) based on molecular and morphological data

Lappula Moench includes ca. 70 species and exhibits a wide range of nutlet variation. Currently, the evolutionary relationships among species of Lappula have not been examined; therefore, to elucidate phylogenetic relationships and morphological evolution within Lappula and related genera, we conducted phylogenetic analyses with matrices that include 48 species as well as four DNA regions (ITS, trnL-trnF, rpS16 and psbA-trnH) and 18 morphological characters. These matrices were analyzed using maximum parsimony, maximum likelihood, and Bayesian inference methods. Analyses of the combined molecular and morphological data result in a phylogeny that is better resolved than that based solely on molecular sequence data. Phylogenetic results suggest that the current infrageneric classification of Lappula, at least at the subsectional and series level, is artificial. The evolutionary patterns of 18 morphological characters are investigated in a phylogenetic context. In Lappula, nutlet homomorphism and small corollas are resolved as ancestral, while nutlet heteromorphism and larger corollas are derived.     

Mutational dynamics and phylogenetic utility of noncoding chloroplast DNA

Introns and spacers are a rich and well-appreciated information source for evolutionary studies in plants. Compared to coding sequences, the mutational dynamics of introns and spacers is very different, involving frequent microstructural changes in addition to substitutions of individual nucleotides. An understanding of the biology of sequence change is required for correct application of molecular characters in phylogenetic analyses, including homology assessment, alignment coding, and tree inference. The widely used term “indel” is very general, and different kinds of microstructural mutations, such as simple sequence repeats, short tandem repeats, homonucleotide repeats, inversions, inverted repeats, and deletions, need to be distinguished. Noncoding DNA has been indispensable for analyses at the species level because coding sequences usually do not offer sufficient variability. A variety of introns and spacers has been successfully applied for phylogeny inference at deeper levels (major lineages of angiosperms and land plants) in past years, and phylogenetic structure R in intron and spacer data sets usually outperforms that of coding-sequence data sets. In order to fully utilize their potential, the molecular evolution and applicability of the most important noncoding markers (the trnT–trnF region comprising two spacers and a group I intron; the trnS–G region comprising one spacer and a group II intron in trnG; the group II introns in petD, rpl16, rps16, and trnK; and the atpB–rbcL and psbA–trnG spacers) are reviewed. The study argues for the use of noncoding DNA in a spectrum of applications from deep-level phylogenetics to speciation studies and barcoding, and aims at outlining molecular evolutionary principles needed for effective analysis.     

Molecular phylogeny of the endemic fern genera Cyrtomidictyum and Cyrtogonellum (Dryopteridaceae) from East Asia

Cyrtomidictyum Ching and Cyrtogonellum Ching are two eastern Asian endemic genera whose taxonomic affinities and phylogenetic relationships have long been controversial. The main uncertainty surrounds the separation of the two genera from the species-rich genus Polystichum. Here we present a phylogenetic study focusing on the phylogenetic relationships of these polystichoid ferns. We reconstructed the relationships based on DNA sequence variation in four chloroplast genome regions, rbcL, atpB, and the intergenic spacers (IGS) rps4-trnS and trnL-trnF. Maximum likelihood and Bayesian inference analyses confirm earlier results that were based on less comprehensive taxon sampling and either only a single gene (rbcL) or two IGS (rps4-trnS and trnL-trnF). Cyrtomidictyum is the sister of the clade of polystichoid ferns that includes Cyrtogonellum, Cyrtomium subser. Balansana and three sections of Polystichum. Cyrtogonellum groups with several species of Polystichum, and constitutes the sister taxon to Polystichum sect. Sphaenopolystichum. We support the recognition of Cyrtomidictyum as circumscribed initially, rather than expansion of the genus to include either several Polystichum species or Cyrtogonellum, some Polystichum and Cyrtomium species. The monophyly of Cyrtomidictyum is supported by morphological characters such as once-pinnate leaves, free venation, prolongated leaf apices, and exindusiate sori. Two synapomorphic indels in the chloroplast genome, one 15-bp deletion in rps4-trnS, and one 3-bp insertion in trnL-trnF further differentiate Cyrtomidictyum from other polystichoid ferns. The close affinity of Cyrtogonellum to section Sphaenopolystichum of Polystichum s.s. is highly supported by molecular data. However, no shared morphological characters or molecular indels have been detected, although the distinctness of Cyrtogonellum is shown by a 13-bp insertion in the rps4-trnS alignment.     

Hybridization between two oil-secreting orchids in South Africa

Natural hybrids among the specialized terrestrial oil-secreting orchids of South Africa are extremely rare even where multiple closely related species co-occur. We found putative hybrids between Pterygodium catholicum Sw. and P. acutifolium Lindl., two closely related oil-secreting orchids that lack morphological barriers to inter-breeding. The purpose of this study was to confirm the parentage of the putative hybrids using molecular data from one nuclear (ITS) and two plastid (matK-trnK and trnL/F introns) DNA regions. Phylogenetic analyses of sequences as well as nucleotide substitution patterns of the putative hybrids, putative parents, and their closest relatives were consistent with a hypothesis of hybridization. We suggest that the hybrids were the result of visits to both orchids by a single species of oil-collecting bee during a brief period of flowering overlap. These results suggest that the rarity of hybrids between these orchids is due to factors other than genetic incompatibility.     

Trichome micromorphology in Alcea L. and allied genera (Malvaceae) and its systematic implication

Trichomes of 26 species of Alcea (Malvaceae) were investigated using light (LM) and scanning electron microscopy (SEM). The trichomes show a great micromorphological variation, which provides data useful for species delimitation in Alcea. Two basic types of trichomes could be distinguished in Alcea and allied genera: glandular and eglandular. The glandular trichomes could in turn be subdivided into two subtypes: capitate and clavate. The eglandular trichomes could be subdivided into five subtypes: simple, fascicled, stellate, fascicled-stellate and pluri-radiate. Characters of taxonomic interest are: trichome density (glabrous to dense), number of arms per trichome, orientation relative to the epidermal surface (appressed to erect) and presence/absence of a stalk. According to the results the species of Alcea can be divided into four informal groups based on trichome types. The results further support the exclusion of the annual Althaea species from the perennial ones and their close relationship to Malva. In addition, a close relationship between perennial Althaea and basal Alcea lineages is supported. Based on the evolutionary framework provided by recent molecular phylogenetic investigations, the following trends can be observed in the Malva alliance: long and narrow-armed trichomes are primitive in relation to short and thick-armed trichomes; dense indumentum coverage is primitive in relation to moderately dense or glabrous ones; presence of simple hairs on stem (particularly on leaves) is more advanced than their absence; spreading villous-stellate and fascicled trichomes are more advanced than appressed stellate ones. Clavate trichomes, which were found exclusively in a few species of Alcea, should be considered as a derived state in relation to capitate ones, and they may provide a synapomorphy for the crown group of Alcea.     

Age Estimates for the Buckwheat Family Polygonaceae Based on Sequence Data Calibrated by Fossils and with a Focus on the Amphi-Pacific Muehlenbeckia

The buckwheat family Polygonaceae is a diverse group of plants and is a good model for investigating biogeography, breeding systems, coevolution with symbionts such as ants and fungi, functional trait evolution, hybridization, invasiveness, morphological plasticity, pollen morphology and wood anatomy. The main goal of this study was to obtain age estimates for Polygonaceae by calibrating a Bayesian phylogenetic analysis, using a relaxed molecular clock with fossil data. Based on the age estimates, we also develop hypotheses about the historical biogeography of the Southern Hemisphere group Muehlenbeckia. We are interested in addressing whether vicariance or dispersal could account for the diversification of Muehlenbeckia, which has a “Gondwanan” distribution.Eighty-one species of Polygonaceae were analysed with MrBayes to infer species relationships. One nuclear (nrITS) and three chloroplast markers (the trnL-trnF spacer region, matK and ndhF genes) were used. The molecular data were also analysed with Beast to estimate divergence times. Seven calibration points including fossil pollen and a leaf fossil of Muehlenbeckia were used to infer node ages.Results of the Beast analyses indicate an age of 110.9 (exponential/lognormal priors)/118.7 (uniform priors) million years (Myr) with an uncertainty interval of (90.7–125.0) Myr for the stem age of Polygonaceae. This age is older than previously thought (Maastrichtian, approximately 65.5–70.6 Myr). The estimated divergence time for Muehlenbeckia is 41.0/41.6 (39.6–47.8) Myr and its crown clade is 20.5/22.3 (14.2–33.5) Myr old. Because the breakup of Gondwana occurred from 95–30 Myr ago, diversification of Muehlenbeckia is best explained by oceanic long-distance and maybe stepping-stone dispersal rather than vicariance. This study is the first to give age estimates for clades of Polygonaceae and functions as a jumping-off point for future studies on the historical biogeography of the family.     

Chemical and phylogenetic relationships among Aristolochia L. (Aristolochiaceae) from southeastern Brazil

In this report, a molecular phylogeny based on the plastid gene matK and on the region between the genes trnL and trnF, and a chemical relationship based on the pattern of sesquiterpenes, is proposed for Aristolochia species from southeastern Brazil. We found that Aristolochia is a monophyletic genus and species considered to be derived contain labdanoic acids (LAs) in their leaves. The phenetic relationship recovered with sesquiterpenes did not agree with the phylogenetic relationships for Aristolochia, and three main clusters were recognized, namely, germacrene-D, germacrene-C and Z-caryophyllene groups. The presence of different sesquiterpene structures in species that are phylogenetically closely related may reflect adaptations to avoid predation of herbivores specialized in feeding on Aristolochiaceae plants.     

Gagea bohemica (Liliaceae), a highly variable monotypic species within Gagea sect. Didymobulbos

Abstract

Gagea bohemica s.l. (Liliaceae) consists of two morphologically extreme forms (saxatilis and bohemica) which depending on the varying opinions of the authors are considered as separate species, subspecies or as a single variable species. In this study, morphological (form and length of perianth segments, pilosity of pedicles and peduncles) and molecular data (cpDNA trnL–trnF IGS) of 55 samples corresponding to 43 populations from Western Europe to the Mediterranean area and eastern Caucasus were investigated. G. bohemica (Zauschn.) Schult. & Schult. f. represents a highly variable monotypic species from both morphological and karyological (2n = 24, 36, 48, 60, 72) aspects. Based on the molecular and morphological data presented here, a differentiation between specific and infraspecific taxa is not possible. We hypothesize that the morphological variability of this species is largely influenced by different site conditions and ploidy level.     

Phylogenetics and taxonomic delimitation of the genus Guizotia (Asteraceae) based on sequences derived from various chloroplast DNA regions

Parsimony-based phylogenetic analyses of the genus Guizotia were undertaken based on DNA sequence data from the following chloroplast DNA (cpDNA) regions: trnT-trnL, trnL-trnF, trnY-rpoB, trnC-petN, psbM-trnD and rps16-trnQ intergenic spacers, trnL, rps16 and matK-5′trnK introns and matK gene. Out of the 26 primers used in this study, 14 were newly designed. The study was conducted to determine (1) the closest relative of Guizotia abyssinica, (2) the taxonomic status of some Guizotia taxa and (3) the subtribal placement of Guizotia in the tribe Heliantheae. The analyses of the sequence data showed that G. abyssinica, G. scabra ssp. scabra, G. scabra ssp. schimperi and G. villosa are phylogenetically closely related. However, G. scabra ssp. schimperi appeared as the most closely related taxon to G. abyssinica. Based on this phylogenetic analysis, we suggest that the two subspecies of G. scabra are better treated as separate species. The analysis also clearly demonstrated that “Chelelu” and “Ketcha” are distinct Guizotia species. The trnT-trnL and trnL-trnF intergenic spacer-based phylogenetic analysis of various subtribes of the tribe Heliantheae strongly supports the placement of the genus Guizotia within the subtribe Milleriinae.     

Evolution of trnF(GAA) pseudogenes in cruciferous plants

In several studies we used the 5′-trnL(UAA)–trnF(GAA) region of the chloroplast DNA for phylogeographic reconstructions, gene diversity calculations and phylogenetic analyses among the genera Arabidopsis and Boechera. Despite the fact that extensive gene duplications are rare within the chloroplast genome of higher plants, within several genera of the Brassicaceae the anticodon domain of the trnF(GAA) gene exhibit extensive gene duplications with 1–12 tandemly repeated copies in close 5′-proximity of the functional gene. A recent re-examination and additional analysis of trnL(UAA)–trnF(GAA) regions from numerous cruciferous taxa not only reveal extensive trnF gene duplications, but also favour the hypothesis that in cruciferous taxa at least four independent phylogenetic lineages are characterized by these pseudogenes. Among these lineages there is one major clade of taxa carrying pseudogenes indicating an ancient split in crucifer evolution. In two case studies, Boechera and Arabidopsis, intra- and inter-molecular recombinations have been shown to be the reason for the reciprocal exchange of several similar motifs. However, functional constraints might favour two to three or five to six copies as shown for Arabidopsis and Boechera. Herein, we compare the occurrence and distribution of pseudogene copy number in the framework of a comprehensive survey of cpDNA haplotype variation in Boechera, the former genus Cardaminopsis and Arabidopsis thaliana and comment on the value of such kind of mutations in phylogenetic and evolutionary reconstructions.     

Phylogeny and classification of Rosaceae

Phylogenetic relationships among 88 genera of Rosaceae were investigated using nucleotide sequence data from six nuclear (18S, gbssi1, gbssi2, ITS, pgip, and ppo) and four chloroplast (matK, ndhF, rbcL, and trnL-trnF) regions, separately and in various combinations, with parsimony and likelihood-based Bayesian approaches. The results were used to examine evolution of non-molecular characters and to develop a new phylogenetically based infrafamilial classification. As in previous molecular phylogenetic analyses of the family, we found strong support for monophyly of groups corresponding closely to many previously recognized tribes and subfamilies, but no previous classification was entirely supported, and relationships among the strongly supported clades were weakly resolved and/or conflicted between some data sets. We recognize three subfamilies in Rosaceae: Rosoideae, including Filipendula, Rubus, Rosa, and three tribes; Dryadoideae, comprising the four actinorhizal genera; and Spiraeoideae, comprising Lyonothamnus and seven tribes. All genera previously assigned to Amygdaloideae and Maloideae are included in Spiraeoideae. Three supertribes, one in Rosoideae and two in Spiraeoideae, are recognized.     

Cytoplasmic diversity,phylogenetic relationships and molecular evolution of Tunisian Citrus species as inferred from mutational events and pseudogene of chloroplast trnL-trnF spacer

The genus Citrus L. is among the most important fruit trees in the world. In this report, cytoplasmic polymorphism of twenty seven Tunisian Citrus cultivars was explored using the chloroplast trnL-trnF intergenic spacer. Chloroplast sequences showed variation in length and nucleotide content. Haplotype and nucleotide diversity showed low variations. Molecular phylogenetic tree identifies Citrus maternal origins and demonstrates two major groups distinguishing between mandarin and pummelo groups. The trnL-trnF intergenic spacer showed one copy of pseudogene of the original trnF gene in 27 Citrus species at position 275 bp with a size varying from 49 to 63 bp. The anticodon domain was identified as the most conserved element, but one transversion (T−>C) was found in the D-domain. Meanwhile, one transversion (T−>A) and one transition (T−>G) were found in the T-domain. Neutrality tests (Tajima, Fu & Li and Fu) which revealed positive and non-significant values and Pi and θ_W assume a neutral model of evolution and advocated a constant population size. The study demonstrates the resolving power of trnL-trnF sequence data to prove both pummelo and mandarin gene pool’s contribution in the development of Tunisian secondary species and inferring their genetic and phylogenetic relationships.     

Phylogenetic status of Vavilovia formosa (Fabaceae-Fabeae) based on nrDNA ITS and cpDNA sequences

The phylogenetic status of the monotypic genus Vavilovia was studied using nrDNA ITS and cpDNA trnL-F and trnS-G regions. The results from the analysis of each dataset and the combined dataset, revealed that Vavilovia is closely related to Pisum, forming a group that is sister to Lathyrus. The molecular data and some morphological and biological characteristics strongly indicate that Vavilovia should be subsumed under Pisum, as Pisum formosum.     

Interspecific relationships and origins of Taxaceae and Cephalotaxaceae revealed by partitioned Bayesian analyses of chloroplast and nuclear DNA sequences

The precise delimitation of Taxaceae and Cephalotaxaceae is not totally resolved. Some contradicting taxonomic proposals have been published, which demonstrates the difficulties in establishing a natural classification of the families and especially in proposing a relevant treatment within the genera Taxus and Cephalotaxus. The aims of this study are to contribute to the phylogeny and specific delineation of the two conifer families on the basis of molecular data. A cladistic analysis of the sequences of five chloroplast (matK, rbcL, trnL, trnL-trnF spacer, and psbA-trnH spacer) and one nuclear (ITS) molecular markers was carried out, both individually and in combination, by distance, parsimony, likelihood, and Bayesian methods. The results confirm that the two families are monophyletic. In the genus Taxus, T. floridana is the first-branching taxon; T. brevifolia and T. globosa cluster together and are sister to T. baccata; the endemic T. yunnanensis clusters with T. wallichiana in subclade B and is only distantly related with the other four Taxus species in China (subclade A); T. fuana is closer to T. baccata than to other Taxus species. Torreya jackii and A. formosana are the first-branching species within Torreya and Amentotaxus, respectively. C. koreana and C. wilsoniana could be treated as two varieties of C. harringtonia. The ancestral distribution area of Taxaceae and Cephalotaxaceae is restricted either to Southwest China or Southeast China by DIVA analysis. The relaxed molecular clock indicates that the deepest divergences in Taxus go back to the late-Cretaceous. psbA-trnH, rbcL third codon position, and matK first codon position contributed most to the separation of taxa in Discriminant function analysis. Our results confirm, on a basis of multiple molecular markers and a complete sampling of basic species, the suggested monophyly of Taxaceae and Cephalotaxaceae and propose interspecific relationships within each group, with profound nomenclatural and taxonomic implications. Combination of partitioned Bayesian analysis and likelihood-based methods produced a more robust phylogenetic hypothesis for the two studied families.     

基于形态学特征和分子数据的中国缺齿藓科初步研究

为探讨缺齿藓类与真藓科、提灯藓科的系统关系,理清缺齿藓科的系统位置和中国缺齿藓科分类问题,该研究以中国分布的缺齿藓科植物和相关类群4 000余份标本为材料,进行详细的形态学研究,并选用其中35种、40份样品的4个DNA片段(rps4、trnG、trnL-trnF、atpB-rbcL)联合数据用于分子系统分析,采用邻接法(NJ)和最大似然法(ML)构建分子树。结果表明:(1)在分子树中,缺齿藓类与真藓科植物分别聚在具有高支持率的不同分支上,叶形、叶细胞等形态学特征也有较大差异,缺齿藓类应从广义的真藓科分出。(2)在分子树中,虽然缺齿藓类与提灯藓科植物聚在同一分支中,但无形态学的共源性状,二者不应视为一个单系类群。(3)缺齿藓科是一个自然类群,缺齿藓科内属间存在着密切的系统关系,缺齿藓科的主要识别特征为:植物体小型,茎常分枝;叶形和叶细胞为丝瓜藓型(Pohlia-like),披针形至长椭圆形,中上部细胞狭长,线状菱形或蠕虫形;生殖苞多生于新生枝顶;蒴齿为互生双齿层,常有不同程度的退化或一层蒴齿缺失,稀双层蒴齿缺失。(4)中国缺齿藓科包含有5属,即缺齿藓属(Mielichhoferia)、丝瓜藓属(Pohlia)、拟丝瓜藓属(Pseudopohlia)、合齿藓属(Synthetodontium)和小叶藓属(Epipterygium),目前为止共计34种(含种下分类单位)。     

Phylogenetic relationships of Ruteae (Rutaceae): new evidence from the chloroplast genome and comparisons with non-molecular data

Phylogenetic analyses of three cpDNA markers (matK, rpl16, and trnL–trnF) were performed to evaluate previous treatments of Ruteae based on morphology and phytochemistry that contradicted each other, especially regarding the taxonomic status of Haplophyllum and Dictamnus. Trees derived from morphological, phytochemical, and molecular datasets of Ruteae were then compared to look for possible patterns of agreement among them. Furthermore, non-molecular characters were mapped on the molecular phylogeny to identify uniquely derived states and patterns of homoplasy in the morphological and phytochemical datasets. The phylogenetic analyses determined that Haplophyllum and Ruta form reciprocally exclusive monophyletic groups and that Dictamnus is not closely related to the other genera of Ruteae. The different types of datasets were partly incongruent with each other. The discordant phylogenetic patterns between the phytochemical and molecular trees might be best explained in terms of convergence in secondary chemical compounds. Finally, only a few non-molecular synapomorphies provided support for the clades of the molecular tree, while most of the morphological characters traditionally used for taxonomic purposes were found to be homoplasious. Within the context of the phylogenetic relationships supported by molecular data, Ruta, the type genus for the family, can only be diagnosed by using a combination of plesiomorphic, homoplasious, and autapomorphic morphological character states.     

New light on phylogeny and taxonomy of the Eurasian Gagea villosa–G. fragifera complex (Liliaceae)

The typification of the name Gagea brentae Evers (a lectotype in GZU is designated here) and studies of living topotype material, led us to conclude that G. brentae is a full synonym of G. fragifera, sharing morphological, karyological (2n=84) and molecular (ITS region, trnL–trnF IGS, psbA–trnH IGS) features with the latter species. Gagea fragifera, as newly circumscribed here, shows a close relationship with G. villosa (M. Bieb.) Sweet and, above all, with G. glacialis K. Koch (possibly a hybridogenous taxon). In short, our new morphological and molecular data provide new evidence for hybridization and introgression between the closely related G. villosa and G. fragifera (both in G. sect. Didymobulbos).