Phylogenetic analysis of the non-pathogenic genusSpiromastix (Onygenaceae) and related onygenalean taxa based on large subunit ribosomal DNA sequences

The phylogenetic positioning of the non-pathogenic genusSpiromastix in the Onygenales was studied based on large subunit rDNA (LSU rDNA) partial sequences (ca. 570 bp.). FourSpiromastix species and 28 representative taxa of the Onygenales were newly sequenced. Phylogenetic trees were constructed by the neighbor-joining (NJ) method and evaluated by the maximum parsimony (MP) method with the data of 13 taxa retrieved from DNA databases.Spiromastix and dimorphic systemic pathogens,Ajellomyces andParacoccidioides, appear to be a monophyletic group with 74% bootstrap probability (BP) in the NJ tree constructed with the representative taxa of the Onygenales. The tree topology was concordant with the NJ tree based on SSU rDNA sequences of our previous work and corresponded to the classification system of the Onygenales by Currah (1985) and its minor modification by Udagawa (1997) with the exception of the classification of the Onygenaceae. The Onygeneceae sensu Udagawa may still be polyphyletic, since three independent lineages were recognized. The taxa forming helicoid peridial appendages were localized to two clades on the tree. The topology of the NJ tree constructed withSpiromastix and its close relatives suggested that the helicoid peridial appendages were apomorphic and acquired independently in the two clades of the Onygenales.     

Ubiquinone systems in fungi. V. Distribution and taxonomic implications of ubiquinones in Eurotiales, Onygenales and the related plectomycete genera, except for Aspergillus, Paecilomyces, Penicillium, and their related teleomorphs

The ubiquinone (coenzyme Q) systems were determined for 176 teleomorphic isolates, 14 anamorphic isolates, and three samples of fruit-bodies of Dendrosphaera eberhardtii, which belonged to Eurotiales, Onygenales, and related taxa. In Eurotiales, Ascosphaera had Q-9, whereas Bettsia had Q-10. All isolates of Monascaceae had the Q-10 system, whereas those of four genera of Pseudeurotiaceae had the Q-10(H₂) system. The Q-10(H₂) system was found in genera of Trichocomaceae, except for Aspergillus, Penicillium, Paecilomyces, and their related taxa. However, Thermoascus had the Q-9 system. In Onygenales, members of Arthrodermataceae had Q-9, and those of Gymnoascaceae had Q-10(H₂). Isolates of Myxotrichaceae were characterized by Q-10(H₂) with few exceptions, which had Q-10. The quinones of Onygenaceae belonged to complex systems, i.e., Q-9, 0-10 and 0-10(H₂), and a combination of two systems. Families Onygenaceae and Trichocomaceae are likely a phylogenetic heterogeneity. Ubiquinone analysis provides a very useful criterion of great promise for classifying eurotialean taxa and also for identifying their isolates.     

Molecular phylogeny and radiation time of Erysiphales inferred from the nuclear ribosomal DNA sequences

Phylogenetic relationships of Erysiphales within Ascomycota were inferred from the newly determined sequences of the 18S rDNA and partial sequences of the 28S rDNA including the D1 and D2 regions of 10 Erysiphales taxa. Phylogenetic analyses revealed that the Erysiphales form a distinct clade among ascomycetous fungi suggesting that the Erysiphales diverged from a single ancestral taxon. The Myxotrichaceae of the Onygenales was distantly related to the other onygenalean families and was the sister group to the Erysiphales calde, with which it combined to form a clade. The Erysiphales/Myxotrichaceae clade was also closely related to some discomycetous fungi (Leotiales, Cyttariales and Thelebolaceae) including taxa that form cleistothecial ascomata. The present molecular analyses as well as previously reported morphological observations suggest the possible existence of a novel evolutionary pathway from cleistothecial discomycetous fungi to Erysiphales and Myxotrichaceae. However, since most of these fungi, except for the Erysiphales, are saprophytic on dung and/or plant materials, the questions of how and why an obligate biotroph like the Erysiphales radiated from the saprophytic fungi remain to be addressed. We also estimated the radiation time of the Erysiphales using the 18S rDNA sequences and the two molecular clockes that have been previously reported. The calculation showed that the Erysiphales split from the Myxotrichaceae 190–127 myr ago. Since the radiation time of the Erysiphales does not exceed 230 myr ago, even when allowance is made for the uncertainty of the molecular clocks, it is possible to consider that the Erysiphales evolved after the radiation of angiosperms. The results of our calculation also showed that the first radiation within the Erysiphales (138–92 myr ago) coincided with the date of a major diversification of angiosperms (130–90 myr ago). These results may support our early assumption that the radiation of the Erysiphales coincided with the evolution of angiosperm plants. Contribution No. 152 from the Laboratory of Plant Pathology, Mie University     

Host Associations Between Fungal Root Endophytes and Boreal Trees

Fungal root endophytes colonize root tissue concomitantly with mycorrhizal fungi, but their identities and host preferences are largely unknown. We cultured fungal endophytes from surface-sterilized Cenococcum geophilum ectomycorrhizae of Betula papyrifera, Abies balsamea, and Picea glauca from two boreal sites in eastern Canada. Isolates were initially grouped on the basis of cultural morphology and then identified by internal transcribed spacer ribosomal DNA sequencing or by PCR restriction fragment length polymorphism. Phylogenetic analysis of the sequence data revealed 31 distinct phylotypes among the isolates, comprising mainly members of the ascomycete families Helotiaceae, Dermateaceae, Myxotrichaceae, and Hyaloscyphaceae, although other fungi were also isolated. Multivariate analyses indicate a clear separation among the endophyte communities colonizing each host tree species. Some phylotypes were evenly distributed across the roots of all three host species, some were found preferentially on particular hosts, and others were isolated from single hosts only. The results indicate that fungal root endophytes of boreal trees are not randomly distributed, but instead form relatively distinct assemblages on different host tree species.     

The Ajellomycetaceae, a new family of vertebrate-associated Onygenales

Phylogenies inferred from the analysis of DNA sequence data have shown that the Onygenales contains clades that do not correspond with previously described families. One lineage identified in recent molecular phylogenetic studies includes the dimorphic pathogens belonging to the genera Ajellomyces, Emmonsia and Paracoccidioides. To evaluate the degree of support for this lineage and determine whether it includes additional taxa, we examined relationships among the members of this clade and selected saprobic onygenalean taxa based on maximum-parsimony analyses of partial nuclear large RNA subunit (LSU) and internal transcribed spacer (ITS) sequences. A clade distinct from the Onygenaceae was found to encompass Ajellomyces (including the anamorph genera Blastomyces, Emmonsia and Histoplasma) and Paracoccidioides brasiliensis. The members of this lineage are saprobic and pathogenic vertebrate-associated taxa distinguished by their globose ascomata with coiled appendages, muricate globose or oblate ascospores, and lack of keratinolytic activity. Anamorphs are solitary aleurioconidia or irregular alternate arthroconidia. Based on molecular data and on morphological and physiological similarities among these taxa, we propose the new family, Ajellomycetaceae.     

Ubiquinone system of the form-genusChrysosporium

The ubiquinone (coenzyme Q: Q) system of 17 strains of the form-genusChrysosporium was analyzed by high performance liquid chromatography (HPLC) and found to show a heterogeneous distribution of the major ubiquinone. Q-9, Q-10 or Q-10(H₂) was found to be the major ubiquinone in 3, 9 and 5 strains, respectively. It was further demonstrated that the teleomorphs of the species characterized by Q-9 and Q-10 could be classified into two separate families, Arthrodermataceae (Q-9) and Onygenaceae (Q-10), which were defined within the revised order Onygenales by Currah. Teleomorphs ofChrysosporium species having Q-10(H₂) have not been found. This paper also includes the ubiquinone system of dermatophytes which relate to the form-genusChrysosporium morphologically.     

SSU rDNA sequence support for a close relationship between the elaphomycetales and the Eurotiales and Onygenales

Based on parsimony analyses of eight new SSU rDNA sequences and 24 homologous sequences retrieved from the DNA databases, we suggest a possible phylogenetic relationship of Elaphomycetales with Eurotiales and Onygenales. Our three includedElaphomyces sequences strongly cluster together (bootstrap value 100%) within a monophyletic group (100%) of Elaphomycetales, Eurotiales, and Onygenales. Earlier reports that another cleistothecial lineage (Erysiphe) is related to Leotiales, are supported by our discovery that also another cleistothecial species,Amylocarpus encephaloides, shows affinity to Leotiales. Ascosphaeraceae and Eremascaceae are possibly better accommodated in Onygenales. We describe a new DNA extraction method in which sonication is used to disrupt thick-walled spores. It is useful for both fresh and dried fungal material.     

Phylogeny and evolution of the powdery mildew fungi (Erysiphales,Ascomycota) inferred from nuclear ribosomal DNA sequences

Powdery mildew fungi (Erysiphales, Ascomycota) are obligate biotrophs that infect a wide range of angiosperms. Phylogenetic analyses based on the nucleotide sequences of the nuclear ribosomal DNA revealed that the powdery mildew fungi are divided into five major lineages. The respective lineage was well defined by the morphology of conidial stage, but not of ascomata. In this fungal group, tree-parasitic taxa are generally ancestral, and multiple events of host expansion from trees to herbs have occurred within the respective lineage. Accompanying the host expansion to herbs, simplification of appendage morphology has occurred multiple times. The simple, mycelioid appendages are thus a result of convergence. The host expansion route was investigated in detail in the tribe Cystotheceae. Two sections of the genus Sphaerotheca were derived from the genus Podosphaera separately. The section Magnicellulatae was derived from a Podosphaera species parasitic to Prunus (Rosaceae), acquired parasitism to the Scrophulariaceae, and then expanded host range into the Asteraceae. After genetic radiation on the Asteraceae, they further expanded their host ranges into other plant families. According to the molecular clock (1.26%/100 million years, myr) reported by Berbee and Taylor, splitting of the Erysiphales and the Myxotrichaceae and first divergence within the Erysiphales was calculated to have occurred 100 and 76myr ago, respectively.     

Evidence from DNA nucleotide sequences and ISSR profiles indicates paraphyly in subspecies of the Southern Grey Shrike (Lanius meridionalis)

We obtained DNA sequence data from mitochondrial (cytochrome b) and nuclear genes (myoglobin and ornithine decarboxylase) to reconstruct the phylogenetic relationships among eight species of shrikes (Lanius). Phylogenetic analyses based on maximum parsimony, maximum likelihood and Bayesian inference all converged into a congruent topology and defined several well-supported clades. Our multi-gene approach based on nucleotide sequences from fast-evolving and conserved genes strongly supported the paraphyly of Southern Grey Shrikes (Lanius meridionalis). The Canary Islands subspecies (L. m. koenigi) differed significantly from its European counterpart (L. m. meridionalis). Furthermore, the genetic distinctiveness of L. m. koenigi was confirmed by ISSR genomic fingerprinting. By contrast, we did not find evidence to distinguish the Canarian Southern Grey Shrike from L. m. algeriensis on the African mainland (Tunisia), and therefore these two taxa may be considered as synonymous. Together, they correspond to a separate species. The origin of the taxa investigated in this study might have originated about 6 Mya at the Miocene/Pliocene boundary when a remarkable worldwide faunal turnover and global vegetation change occurred. The Lanius genus represents a complex and taxonomically challenging group that requires additional research.     

Implications of molecular systematic analyses on the conservation of rare and threatened taxa: Contrasting examples from Malvaceae

Systematic research provides essential evidence for setting conservation priorities for rare and endangered taxa. Phylogenetic analyses can identify cryptic, genetically distinct lineages as well as actively interbreeding, and hence, non-distinctive lineages earlier perceived as separate taxa. A major aim of this study was to identify genetically distinct, rare lineages within two Malvaceae sister-genera, Sidalcea and Eremalche. The focus was two taxon-pairs each consisting of one rare and one more common taxon. The results demonstrate that even within two closely related genera, with a large number of rare taxa, molecular phylogenetic analyses can reveal contrasting degrees of evolutionary divergence and thus contrasting conservation implications for threatened taxa. Contrary to expectations, the substitution rate in the nuclear ribosomal transcribed spacers for annual Eremalche did not correspond to the faster evolutionary rate of annuals – compared to perennials – detected earlier within Sidalcea. Branch lengths in the (annual) Eremalche clade were shorter than those of annual members of Sidalcea. The phylogenetic analyses showed that the rare and endangered S. keckii and E. kernensis each are most closely related to a common species that has been regarded as insufficiently distinct to warrant separate taxonomic status. An additional aim of the study was to test the utility of the Phylogenetic Diversity (PD) measure to formalize the procedure of prioritizing conservation efforts. The measure demonstrated S. keckii (but not E. kernensis) to be genetically distinct from its closest relative and a good candidate for conservation. The PD measure was earlier used for assessing conservation priorities for areas, but proved useful to more objectively suggest conservation priorities among threatened taxa. Because this measure is calculated directly from the data, it retains more character information and gives a better representation of genetic diversity than other measures relying on tree topologies.     

PRP8 Intein in Onygenales: Distribution and Phylogenetic Aspects

Inteins (internal proteins) are mobile genetic elements, inserted in housekeeping proteins, with self-splicing properties. Some of these elements have been recently pointed out as modulators of genetic expression or protein function. Herein, we evaluated, in silico, the distribution and phylogenetic patterns of PRP8 intein among 93 fungal strains of the order Onygenales. PRP8 intein(s) are present in most of the species (45/49), mainly as full-length inteins (containing both the Splicing and the Homing Endonuclease domains), and must have transferred vertically in all lineages, since their phylogeny reflects the group phylogeny. While the distribution of PRP8 intein(s) varies among species of Onygenaceae family, being absent in Coccidioides spp. and present as full and mini-intein in other species, they are consistently observed as full-length inteins in all evaluated pathogenic species of the Arthrodermataceae and Ajellomycetaceae families. This conservative and massive PRP8 intein presence in Ajellomycetacean and Arthrodermatecean species reinforces the previous idea that such genetic elements do not decrease the fungal fitness significantly and even might play some role in the host–pathogen relationship, at least in these two fungal groups. We may better position the species Ophidiomyces ophiodiicola (with no intein) in the Onygenaceae family and Onygena corvina (with a full-length intein) as a basal member in the Arthrodermataceae family.

     

A Total Evidence Phylogeny of the Arctoidea (Carnivora: Mammalia): Relationships Among Basal Taxa

A total evidence phylogenetic analysis was performed for 14 extant and 18 fossil caniform genera using a data matrix of 5.6 kbp of concatenated sequence data from six independent loci and 80 morphological characters from the cranium and dentition. Maximum parsimony analysis recovered a single most parsimonious cladogram (MPC). The topology of the extant taxa in the MPC agreed with previous molecular phylogenies. Phylogenetic positions for fossil taxa indicate that several taxa previously described as early members of extant families (e.g., Bathygale and Plesictis) are likely stem taxa at the base of the Arctoidea. Taxa in the “Paleomustelidae” were found to be paraphyletic, but a monophyletic Oligobuninae was recovered within this set of taxa. This clade was closely related to the extant genera Gulo and Martes, therefore, nested within the extant radiation of the family Mustelidae. This analysis provides a resolution to several discrepancies between phylogenies considering either fossil taxa or extant taxa separately, and provides a framework for incorporating fossil and extant taxa into comprehensive combined evidence analyses.     

Phylogenetic analysis of the Malvadendrina clade (Malvaceae s.l.) based on plastid DNA sequences

Phylogenetic relationships within Malvaceae s.l., a clade that includes the traditional families Bombacaceae, Malvaceae s.str., Sterculiaceae, and Tiliaceae, have become greatly clarified thanks to recent molecular systematic research. In this paper, we use DNA sequences of four plastid regions (atpB, matK, ndhF, and rbcL) to study relationships within Malvadendrina, one of the two major clades of Malvaceae s.l. The four data sets were generally in agreement, but five terminal taxa manifested highly unexpected affinities in the rbcL partition, and the non-coding sequences of the trnK intron were found to provide limited phylogenetic information for resolving relationships at the base of Malvadendrina. The remaining data strongly support the existence of six major clades within Malvadendrina: Brownlowioideae, Dombeyoideae, Helicteroideae, Malvatheca (comprising Bombacoideae and Malvoideae), Sterculioideae, and Tilioideae. These data also resolve the placement of two problematic taxa: Nesogordonia (in Dombeyoideae) and Mortoniodendron (in Tilioideae). The relationships among the six clades are not definitively resolved, but the best-supported topology has Dombeyoideae as sister to the remainder of Malvadendrina (posterior probability PP=80%) and Sterculioideae as sister to Malvatheca (PP=86%). This early branching position of Dombeyoideae is supported by similarities in floral characters between members of that clade and outgroup taxa in Byttnerioideae. Similarly, the sister-group relationship of Sterculioideae and Malvatheca receives support from androecial characteristics, like subsessile or sessile anthers and an absence of staminodes, shared by these two clades.     

Simaroubaceae,an artificial construct: evidence from rbcL sequence variation

Phylogenetic analyses of rbcL sequence data of representatives of all subfamilies indicate that Simaroubaceae sensu lato is polyphyletic. It represents at least five separate lineages, only three of which (Simarouboideae, Harrisonia, and Kirkioideae) cluster within a robust sapindalean clade. The family is monophyletic only when comprised of members of the subfamily Simarouboideae plus Leitneriaceae, but excluding Harrisonia. Harrisonia is most closely related to Cneorum and Rutaceae. Kirkioideae is distant from Simaroubaceae sensu stricto, although its affinities remain within Sapindales. The other two lineages show an affinity to taxa at some distance from Sapindales: lrvingia with a group of poorly sampled rosid I taxa comprising in part members of Linales and Malphigiales; Picramnia and Alvaradoa cluster together in an isolated position between the broadly comprised groups of rosid I and rosid II. Support for the affinities suggested here is also evident in nonmolecular data sources: wood anatomy, pericarp structure, pollen, and phytochemistry. The elevation of the picramnioid clade, comprising Picramnia and Alvaradoa, to family rank is signaled, and the recognition of Kirkiaceae and Irvingiaceae is substantiated.     

Molecular Phylogeny and Evolution of the Plant-Specific Seven-Transmembrane MLO Family

Abstract Homologues of barley Mlo encode the only family of seven-transmembrane (TM) proteins in plants. Their topology, subcellular localization, and sequence diversification are reminiscent of those of G-protein coupled receptors (GPCRs) from animals and fungi. We present a computational analysis of MLO family members based on 31 full-size and 3 partial sequences, which originate from several monocot species, the dicot Arabidopsis thaliana, and the moss Ceratodon purpureus. This enabled us to date the origin of the Mlo gene family back at least to the early stages of land plant evolution. The genomic organization of the corresponding genes supports a monophyletic origin of the Mlo gene family. Phylogenetic analysis revealed five clades, of which three contain both monocot and dicot members, while two indicate class-specific diversification. Analysis of the ratio of nonsynonymous-to-synonymous changes in coding sequences provided evidence for functional constraint on the evolution of the DNA sequences and purifying selection, which appears to be reduced in the first extracellular loop of 12 closely related orthologues. The 31 full-size sequences were examined for potential domain-specific intramolecular coevolution. This revealed evidence for concerted evolution of all three cytoplasmic domains with each other and the C-terminal cytoplasmic tail, suggesting interplay of all intracellular domains for MLO function.     

Examination of evolutionary relationships in the Cape fossorial skink species complex (Acontinae: Acontias meleagris meleagris) reveals the presence of five cryptic lineages

Variable morphological characters have obscured genealogical relationships in the Cape fossorial skink Acontias meleagris meleagris species complex. Currently the species complex contains four dubious operational taxonomic units (A. meleagris meleagris, A. m. orientalis, A. percivali tasmani and the morph lineicauda) with poorly defined species boundaries. In the present study we examine the evolutionary relationships within the species complex by sampling 24 skink populations from the known geographical distribution in the Western and Eastern Cape provinces of South Africa, representing a total of 119 specimens. We used partial sequence data derived from two mitochondrial DNA genes, 16S rRNA and COI, and one nuclear DNA gene, intron β‐fibrinogen (β‐fibint 7), to examine evolutionary relationships. Phylogenetic relationships were determined using both Maximum Parsimony (MP) and Bayesian inference (BI) from the combined mtDNA, nDNA and the total evidence data. Additionally we employed Maximum likelihood (ML) analyses on the total evidence data that comprised ～1.5 kb. Topologies derived from the combined mtDNA analyses were congruent with the total evidence analyses (mtDNA + nDNA) and retrieved five major clades with strong statistical support inferred from bootstrapping and posterior probabilities. The five clades were genealogically and geographically exclusive, diagnostic at both the mtDNA and nDNA level and characterized by pronounced sequence divergence, with no shared haplotypes between clades. Collectively these results suggest the presence of five putative cryptic operational taxonomic units within the A. meleagris meleagris species complex. Constraining the traditionally recognized taxa always retrieved a statistically worse topology suggesting that considerable taxonomic revision is required. Our results indicate that traditional morphological characters need to be reassessed to define the five novel lineages in the A. meleagris meleagris species complex. The phylogeographic pattern for the fossorial skinks we retrieved was novel compared to phylogeographic studies for codistributed above ground living taxa. These results suggest that the abiotic and biotic factors that impact subterranean taxa may differ from supraterranean taxa.     

Molecular characterization of pezizalean ectomycorrhizas associated with pinyon pine during drought

Recent studies using molecular analysis of ectomycorrhizas have revealed that ascomycete fungi, especially members of the order Pezizales, can be important members of ectomycorrhizal (EM) fungal communities. However, little is known about the ecology and taxonomy of many of these fungi. We used data collected during a wet and a dry period to test the hypothesis that pezizalean EM fungi associated with pinyon pine (Pinus edulis) responded positively to drought stress. We also assessed the phylogenetic relationships among six, unknown pezizalean EM fungi, common to our study sites, using rDNA sequences from the internal transcribed spacer and large subunit (LSU) regions of the ribosomal DNA. Sequences of these fungi were then compared to sequences from known taxa to allow finer-scale identification. Three major findings emerged. First, at two sites, pezizalean EM were 44–95% more abundant during a dry year than a wetter year, supporting the hypothesis that pezizalean EM fungi respond positively to dry conditions. Second, four of the six unknown pezizalean EM fungi associated with P. edulis separated from one another consistently regardless of site or year of collection, suggesting that they represented distinct taxa. Third, comparison with LSU sequences of known members of the Pezizales indicated that these four taxa grouped within the genus Geopora of the family Pyronemataceae. Our results provide further evidence of the importance of pezizalean fungi in the ectomycorrhizal symbiosis and demonstrate high local abundance of members of the genus Geopora in drought-stressed pinyon–juniper woodlands.     

CONCORDANCE OF MOLECULAR AND ULTRASTRUCTURAL DATA IN THE STUDY OF ZOOSPORIC CHLOROCOCCALEAN GREEN ALGAE1

Alternative evolutionary hypotheses generated from features of vegetative cell morphology and motile cell ultra-structure were investigated using a molecular data set. Complete nuclear-encoded small subunit (18S) ribosomal RNA (rRNA) gene sequences were determined for six species (three each) of the chlorococcalean green algae “Neo chloris” and Characium. Based on motile cell ultra-structure, it was previously shown that both genera could be separated into three distinct groups possibly representing three separate orders and two classes of green algae. 18S rRNA gene sequences were also obtained for three additional taxa, Dunaliella parva Lerche, Pediastrum duplex Meyen, and Friedmannia israelensis Chantanachat and Bold. These organisms were selected because each, in turn, is a representative of one of the three ultrastructural groups into which the Neochloris and Characium species are separable. Phylogenetic analyses utilizing the molecular data fully support the ultrastructural findings, suggesting that the similar vegetative cell morphologies observed in these organisms have resulted from convergence.     

Phylogenetic relationships of Combretoideae (Combretaceae) inferred from plastid,nuclear gene and spacer sequences

Phylogenetic relationships of the subfamily Combretoideae (Combretaceae) were studied based on DNA sequences of nuclear ribosomal internal transcribed spacer (ITS) regions, the plastid rbcL gene and the intergenic spacer between the psaA and ycf3 genes (PY-IGS), including 16 species of eight genera within two traditional tribes of Combretoideae, and two species of the subfamily Strephonematoideae of Combretaceae as outgroups. Phylogenetic trees based on the three data sets (ITS, rbcL, and PY-IGS) were generated by using maximum parsimony (MP) and maximum likelihood (ML) analyses. Partition-homogeneity tests indicated that the three data sets and the combined data set are homogeneous. In the combined phylogenetic trees, all ingroup taxa are divided into two main clades, which correspond to the two tribes Laguncularieae and Combreteae. In the Laguncularieae clade, two mangrove genera, Lumnitzera and Laguncularia, are shown to be sister taxa. In the tribe Combreteae, two major clades can be classified: one includes three genera Quisqualis, Combretum and Calycopteris, within which the monophyly of the tribe Combreteae sensu Engler and Diels including Quisqualis and Combretum is strongly supported, and this monophyly is then sister to the monotypic genus Calycopteris; another major clade includes three genera Anogeissus, Terminalia and Conocarpus. There is no support for the monophyly of Terminalia as it forms a polytomy with Anogeissus. This clade is sister to Conocarpus. Electronic Publication