Your search keyword '"Susanne S. Renner"' showing total 6 results

1. Clock-dated phylogeny for 48% of the 700 species of Crotalaria (Fabaceae-Papilionoideae) resolves sections worldwide and implies conserved flower and leaf traits throughout its pantropical range

Author

Alexander, Rockinger, Andréia Silva, Flores, and Susanne S, Renner

Subjects

Climate, Molecular clock, Flowers, GBIF data, Plant Leaves, Polyploidy, Trait evolution, Leaf architecture, Crotalaria, Plastids, Climate types, Flower morphology, Ecosystem, Phylogeny, Research Article

Abstract

Background With some 700 species, the pantropical Crotalaria is among the angiosperm’s largest genera. We sampled 48% of the species from all sections (and representatives of the 15 remaining Crotalarieae genera) for nuclear and plastid DNA markers to infer changes in climate niches, flower morphology, leaf type, and chromosome numbers. Results Crotalaria is monophyletic and most closely related to African Bolusia (five species) from which it diverged 23 to 30 Ma ago. Ancestral state reconstructions reveal that leaf and flower types are conserved in large clades and that leaf type is uncorrelated to climate as assessed with phylogenetically-informed analyses that related compound vs. simple leaves to the mean values of four Bioclim parameters for 183 species with good occurrence data. Most species occur in open habitats

Published

2016

2. Computer vision applied to herbarium specimens of German trees: testing the future utility of the millions of herbarium specimen images for automated identification

Author

Dorit Merhof, Susanne S. Renner, and Jakob Unger

Subjects

0106 biological sciences, Normalization (statistics), JSTOR, Databases, Factual, Machine vision, Feature extraction, Biology, 010603 evolutionary biology, 01 natural sciences, Trees, Server, ddc:570, Germany, Image Processing, Computer-Assisted, Segmentation, Computer vision, Ecology, Evolution, Behavior and Systematics, Herbarium specimens, business.industry, Methodology Article, Plants, Plant Leaves, Identification (information), Herbarium, Test set, Artificial intelligence, Leaf venation, business, Automated identification, Algorithms, Leaf shape, 010606 plant biology & botany

Abstract

BMC evolutionary biology 16, 248 (2016). doi:10.1186/s12862-016-0827-5, Published by BioMed Central, London

Published

2016

3. The temporal build-up of hummingbird/plant mutualisms in North America and temperate South America

Author

Stefan, Abrahamczyk and Susanne S, Renner

Subjects

Plant Nectar, Fossils, Sephanoides, Flowers, Plants, South America, Chronograms, Birds, Phylogeography, Staggered clade ages, North America, Hummingbirds, Patagonia, Animals, Pollination, Symbiosis, Ecosystem, Phylogeny, Plant Physiological Phenomena, Research Article, Coevolution

Abstract

Background The 361 species of hummingbirds that occur from Alaska to Patagonia pollinate ~7,000 plant species with flowers morphologically adapted to them. To better understand this asymmetric diversity build-up, this study analyzes the origin of hummingbird/plant mutualisms in North America and temperate South America, based on new compilations of the 184 hummingbird-adapted species in North America, the 56 in temperate South America, and complete species-level phylogenies for the relevant hummingbirds in both regions, namely five in temperate South America and eight in North America. Because both floras are relatively well sampled phylogenetically, crown or stem ages of many representative clades could be inferred. The hummingbird chronogram was calibrated once with fossils, once with substitutions rates, while plant chronograms were taken from the literature or in 13 cases newly generated. Results The 184 North American hummingbird-adapted species belong to ca. 70 lineages for 19 of which (comprising 54 species) we inferred divergence times. The 56 temperate South American hummingbird-adapted species belong to ca. 35 lineages, for 17 of which (comprising 25 species) we inferred divergence times. The oldest hummingbirds and hummingbird-adapted plant lineages in the South American assemblage date to 16–17 my, those in the North American assemblage to 6–7 my. Few hummingbird-pollinated clades in either system have >4 species. Conclusions The asymmetric diversity build-up between hummingbirds and the plants dependent on them appears to arise not from rapid speciation within hummingbird-pollinated clades, but instead from a gradual and continuing process in which independent plant species switch from insect to bird pollination. Diversification within hummingbird-pollinated clades in the temperate regions of the Americas appears mainly due to habitat specialization and allopatric speciation, not bird pollination per se. Interaction tanglegrams, even if incomplete, indicate a lack of tight coevolution as perhaps expected for temperate-region mutualisms involving nectar-feeding vertebrates. Electronic supplementary material The online version of this article (doi:10.1186/s12862-015-0388-z) contains supplementary material, which is available to authorized users.

Published

2015

4. Correlates of monoicy and dioicy in hornworts, the apparent sister group to vascular plants

Author

Juan Carlos Villarreal and Susanne S. Renner

Subjects

Gametophyte, Trait correlation, biology, Reproduction, Sexual systems, Genetic Variation, Anthocerotophyta, Plants, biology.organism_classification, Chromosome counts, Moss, Hornwort, Polyploid, Sister group, Spore size, Antheridium, Botany, Monoicous, Mating, Ecology, Evolution, Behavior and Systematics, Phylogeny, Research Article

Abstract

Background Whether male and female gametes are produced by single or separate individuals shapes plant mating and hence patterns of genetic diversity among and within populations. Haploid-dominant plants (“bryophytes”: liverworts, mosses and hornworts) can have unisexual (dioicous) or bisexual (monoicous) gametophytes, and today, 68% of liverwort species, 57% of moss species, and 40% of hornwort species are dioicous. The transitions between the two sexual systems and possible correlations with other traits have been studied in liverworts and mosses, but not hornworts. Here we use a phylogeny for 98 of the 200 species of hornworts, the sister group to vascular plants, representing roughly equal proportions of all monoicous and all dioicous species, to test whether transitions in sexual systems are predominantly from monoicy to dioicy as might be expected based on studies of mosses. We further investigate possible correlations between sexual system and spore size, antheridium number, ploidy level, and diversification rate, with character selection partly based on findings in mosses and liverworts. Results Hornworts underwent numerous transitions between monoicy and dioicy. The transition rate from dioicy to monoicy was 2× higher than in the opposite direction, but monoicous groups have higher extinction rates; diversification rates do not correlate with sexual system. A correlation important in mosses, that between monoicy and polyploidy, apparently plays a small role: of 20 species with chromosome counts, only one is polyploid, the monoicous Anthoceros punctatus. A contingency test revealed that transitions to dioicy were more likely in species with small spores, supporting the hypothesis that small but numerous spores may be advantageous for dioicous species that depend on dense carpets of gametophytes for reproductive assurance. However, we found no evidence for increased antheridium-per-chamber numbers in dioicous species. Conclusions Sexual systems in hornworts are labile, and the higher number of extant monoicous species (60%) may be largely due to frequent transitions to monoicy.

Published

2013

5. Evolution and loss of long-fringed petals: a case study using a dated phylogeny of the snake gourds, Trichosanthes (Cucurbitaceae)

Author

Hanno Schaefer, Mats Thulin, Hugo J. de Boer, and Susanne S. Renner

Subjects

Asia, Biologisk systematik, DNA, Plant, Evolution, Zoology, Trichosanthes, Flowers, Biological Systematics, Monophyly, food, Genus, Polyphyly, DNA, Ribosomal Spacer, Hodgsonia, Botany, QH359-425, Molecular clock, Phylogeny, Ecology, Evolution, Behavior and Systematics, Cell Nucleus, Likelihood Functions, biology, Snake gourd, Australia, DNA, Chloroplast, Bayes Theorem, Sequence Analysis, DNA, biology.organism_classification, Biological Evolution, food.food, Petal, Research Article

Abstract

Background The Cucurbitaceae genus Trichosanthes comprises 90–100 species that occur from India to Japan and southeast to Australia and Fiji. Most species have large white or pale yellow petals with conspicuously fringed margins, the fringes sometimes several cm long. Pollination is usually by hawkmoths. Previous molecular data for a small number of species suggested that a monophyletic Trichosanthes might include the Asian genera Gymnopetalum (four species, lacking long petal fringes) and Hodgsonia (two species with petals fringed). Here we test these groups’ relationships using a species sampling of c. 60% and 4759 nucleotides of nuclear and plastid DNA. To infer the time and direction of the geographic expansion of the Trichosanthes clade we employ molecular clock dating and statistical biogeographic reconstruction, and we also address the gain or loss of petal fringes. Results Trichosanthes is monophyletic as long as it includes Gymnopetalum, which itself is polyphyletic. The closest relative of Trichosanthes appears to be the sponge gourds, Luffa, while Hodgsonia is more distantly related. Of six morphology-based sections in Trichosanthes with more than one species, three are supported by the molecular results; two new sections appear warranted. Molecular dating and biogeographic analyses suggest an Oligocene origin of Trichosanthes in Eurasia or East Asia, followed by diversification and spread throughout the Malesian biogeographic region and into the Australian continent. Conclusions Long-fringed corollas evolved independently in Hodgsonia and Trichosanthes, followed by two losses in the latter coincident with shifts to other pollinators but not with long-distance dispersal events. Together with the Caribbean Linnaeosicyos, the Madagascan Ampelosicyos and the tropical African Telfairia, these cucurbit lineages represent an ideal system for more detailed studies of the evolution and function of petal fringes in plant-pollinator mutualisms.

Published

2012

6. Phylogenetics of Cucumis (Cucurbitaceae): Cucumber (C. sativus) belongs in an Asian/Australian clade far from melon (C. melo)

Author

Hanno Schaefer, Susanne S. Renner, and Alexander Kocyan

Subjects

Asia, Evolution, Genes, Plant, Hystrix, Evolution, Molecular, Cucumis melo, Genus, Phylogenetics, Botany, QH359-425, Internal transcribed spacer, Clade, Phylogeny, Ecology, Evolution, Behavior and Systematics, biology, Phylogenetic tree, Australia, DNA, Chloroplast, Biodiversity, Sequence Analysis, DNA, biology.organism_classification, Taxonomy (biology), Cucumis sativus, Cucumis, Research Article

Abstract

Background Melon, Cucumis melo, and cucumber, C. sativus, are among the most widely cultivated crops worldwide. Cucumis, as traditionally conceived, is geographically centered in Africa, with C. sativus and C. hystrix thought to be the only Cucumis species in Asia. This taxonomy forms the basis for all ongoing Cucumis breeding and genomics efforts. We tested relationships among Cucumis and related genera based on DNA sequences from chloroplast gene, intron, and spacer regions (rbcL, matK, rpl20-rps12, trnL, and trnL-F), adding nuclear internal transcribed spacer sequences to resolve relationships within Cucumis. Results Analyses of combined chloroplast sequences (4,375 aligned nucleotides) for 123 of the 130 genera of Cucurbitaceae indicate that the genera Cucumella, Dicaelospermum, Mukia, Myrmecosicyos, and Oreosyce are embedded within Cucumis. Phylogenetic trees from nuclear sequences for these taxa are congruent, and the combined data yield a well-supported phylogeny. The nesting of the five genera in Cucumis greatly changes the natural geographic range of the genus, extending it throughout the Malesian region and into Australia. The closest relative of Cucumis is Muellerargia, with one species in Australia and Indonesia, the other in Madagascar. Cucumber and its sister species, C. hystrix, are nested among Australian, Malaysian, and Western Indian species placed in Mukia or Dicaelospermum and in one case not yet formally described. Cucumis melo is sister to this Australian/Asian clade, rather than being close to African species as previously thought. Molecular clocks indicate that the deepest divergences in Cucumis, including the split between C. melo and its Australian/Asian sister clade, go back to the mid-Eocene. Conclusion Based on congruent nuclear and chloroplast phylogenies we conclude that Cucumis comprises an old Australian/Asian component that was heretofore unsuspected. Cucumis sativus evolved within this Australian/Asian clade and is phylogenetically far more distant from C. melo than implied by the current morphological classification.

Published

2007