Stefan Wanke

Local uses of Aristolochia species and content of nephrotoxic aristolochic acid 1 and 2--a global assessment based on bibliographic sources.

AIMS OF THE STUDY More than 100 cases of nephropathy over the last 10 years caused by the systemic and longer term application of Chinese snakeroot (Aristolochia fangchi) highlighted the risk of using preparations which contain aristolochic acids. On the other hand anecdotal evidence highlights the widespread use of Aristolochia species (Aristolochiaceae) in many regions of the world. Therefore, it was our objective to systematically assess the scientific literature available on the local and traditional use of Aristolochia spp. on a worldwide scale. Our review identifies core species which need to be investigated and which may need monitoring (esp. in national and international trade). METHODS An extensive review of the literature available in libraries in London on the uses of species of Aristolochia was undertaken. Relevant information was extracted and entered into a database for analysis. RESULTS Based on the assessment of 566 reference sources 685 individual sets of data were recorded. Seven species--Aristolochia indica L. (Asia), Aristolochia serpentaria L. (North America), Aristolochia debilis Sieb & Zucch. (China), Aristolochia acuminata Lam (India), Aristolochia trilobata L. (Central/South America, Caribbean), Aristolochia clematitis L. (Europe) and Aristolochia bracteolata Lam. (Africa)--are reported widely as being used medicinally. The medical uses vary, but of particular interest are uses in case of gastrointestinal problems, which is likely to result in repeated exposure to the botanical drugs by an individual. About half of all records relate to uses of Aristolochia species in Asia, one-third to the Americas, a continent which has so far received practically no attention in terms of assessing the risk of using species of Aristolochia. Of the 99 species (plus several identified at genus level only) for which we were able to summarise ethnobotanical information, preliminary phytochemical information is only available for 24 species and some of the most common ones including Aristolochia acuminata have so far not been studied phytochemically. CONCLUSIONS Species of Aristolochia are used medicinally in many regions of the world and both from an ethnopharmacological and a public health perspective this poses a risk. A systematic assessment of the content of aristolochic acids in the most widely used species is needed to evaluate whether their uses pose a potential health risk. In China and Europe species of Aristolochia have been associated with nephropathy and it is important to evaluate whether nephropathy occurs in other parts of the world, especially India and Central America where the use of species of Aristolochia are reported to be commonly used in traditional medicine.

Molecular Phylogeny of Aristolochia sensu lato (Aristolochiaceae) based on Sequences of rbcL, matK, and phyA Genes, with Special Reference to Differentiation of Chromosome Numbers

Abstract The genus Aristolochia sensu lato contains over 400 species from warm temperate to tropical regions worldwide. Taxonomic treatments of Aristolochia have been ambiguous and controversial. In a recent cladistic analysis based on morphological characters, it was proposed that the genus should be divided into four genera in two subtribes. To reconsider the systematics of Aristolochia sensu lato, we reconstructed its phylogeny based on nucleotide sequences of the chloroplast rbcL gene and the nuclear-encoded phytochrome A (phyA) gene for 19 representative species and the chloroplast matK gene of over 80 species. All phylogenetic trees produced with the three genes indicate that Aristolochia sensu lato is a monophyletic group, consisting of two lineages that correspond to the subtribes Aristolochiinae and Isotrematinae. The matK phylogeny shows that each of the lineages includes two sublineages. The Aristolochiinae clade is composed of the Aristolochia sensu stricto and Pararistolochia clades, and the Isotrematinae clade of the Isotrema and Endodeca clades. Chromosome numbers, including newly reported counts for 30 species, are predominantly congruent with the phylogeny: the Aristolochiinae clade shows chromosome numbers of 2n = 6, 12, 14, or 16, while the Isotrematinae clade is characterized by 2n = 32. In the Isotrematinae clade, the paralogous relationships of the phyA gene suggest that polyploidization might have occurred.

SYSTEMATICS OF PIPEVINES: COMBINING MORPHOLOGICAL AND FAST-EVOLVING MOLECULAR CHARACTERS TO INVESTIGATE THE RELATIONSHIPS WITHIN SUBFAMILY ARISTOLOCHIOIDEAE (ARISTOLOCHIACEAE)

A combined phylogenetic analysis of the Aristolochioideae was conducted based on 72 morphological characters and molecular data sets (matK gene, trnK intron, trnL intron, trnL‐trnF spacer). The analysis sampled 33 species as the ingroup, including two species of Thottea, 30 species of Aristolochia, and the monotypic genus Euglypha, which represent all the infrageneric taxa formally described; Saruma henryi and Asarum caudatum were used as the outgroup. The results corroborate a sister‐group relationship between Thottea and Aristolochia and the paraphyly of Aristolochia with respect to Euglypha, which consequently should be included in Aristolochia. Two of the three subgenera within Aristolochia (Isotrema and Pararistolochia) are shown to be monophyletic, whereas the signal obtained from the different data sets about the relationships within subgenus Aristolochia is low and conflicting, resulting in collapsed or unsupported branches. The relationship between the New World and the Old World species of subgenus Aristolochia is conflictive because morphological data support these two groups as monophyletic, whereas molecular data show the monophyletic Old World species of Aristolochia nested within the New World species. A sister‐group relationship is proposed between Aristolochia lindneri and pentandrous species, which suggests that a group of five species from central and southern South America (including A. lindneri) could be monophyletic and sister to Aristolochia subsect. Pentandrae, a monophyletic taxon consisting of ca. 35 species from the southern United States, Mesoamerica, and the West Indies.

Single-copy nuclear genes place haustorial Hydnoraceae within piperales and reveal a cretaceous origin of multiple parasitic angiosperm lineages.

Extreme haustorial parasites have long captured the interest of naturalists and scientists with their greatly reduced and highly specialized morphology. Along with the reduction or loss of photosynthesis, the plastid genome often decays as photosynthetic genes are released from selective constraint. This makes it challenging to use traditional plastid genes for parasitic plant phylogenetics, and has driven the search for alternative phylogenetic and molecular evolutionary markers. Thus, evolutionary studies, such as molecular clock-based age estimates, are not yet available for all parasitic lineages. In the present study, we extracted 14 nuclear single copy genes (nSCG) from Illumina transcriptome data from one of the “strangest plants in the world”, Hydnora visseri (Hydnoraceae). A ∼15,000 character molecular dataset, based on all three genomic compartments, shows the utility of nSCG for reconstructing phylogenetic relationships in parasitic lineages. A relaxed molecular clock approach with the same multi-locus dataset, revealed an ancient age of ∼91 MYA for Hydnoraceae. We then estimated the stem ages of all independently originated parasitic angiosperm lineages using a published dataset, which also revealed a Cretaceous origin for Balanophoraceae, Cynomoriaceae and Apodanthaceae. With the exception of Santalales, older parasite lineages tend to be more specialized with respect to trophic level and have lower species diversity. We thus propose the “temporal specialization hypothesis” (TSH) implementing multiple independent specialization processes over time during parasitic angiosperm evolution.

Fossil evidence for low gas exchange capacities for Early Cretaceous angiosperm leaves

Abstract The photosynthetic gas exchange capacities of early angiosperms remain enigmatic. Nevertheless, many hypotheses about the causes of early angiosperm success and how angiosperms influenced Mesozoic ecosystem function hinge on understanding the maximum capacity for early angiosperm metabolism. We applied structure-functional analyses of leaf veins and stomatal pore geometry to determine the hydraulic and diffusive gas exchange capacities of Early Cretaceous fossil leaves. All of the late Aptian–early Albian angiosperms measured possessed low vein density and low maximal stomatal pore area, indicating low leaf gas exchange capacities in comparison to modern ecologically dominant angiosperms. Gas exchange capacities for Early Cretaceous angiosperms were equivalent or lower than ferns and gymnosperms. Fossil leaf taxa from Aptian to Paleocene sediments previously identified as putative stem-lineages to Austrobaileyales and Chloranthales had the same gas exchange capacities and possibly leaf water relations of their living relatives. Our results provide fossil evidence for the hypothesis that high leaf gas exchange capacity is a derived feature of later angiosperm evolution. In addition, the leaf gas exchange functions of austrobaileyoid and chloranthoid fossils support the hypothesis that comparative research on the biology of living basal angiosperm lineages reveals genuine signals of Early Cretaceous angiosperm ecophysiology.

Structure and biomechanics of trapping flower trichomes and their role in the pollination biology of Aristolochia plants (Aristolochiaceae)

*Catching insects to ensure pollination is one of the most elaborate and specialized mechanisms of insect-plant interactions. Phylogenetically, Aristolochiaceae represent the first angiosperm lineage that developed trap flowers. Here we report the structure and function of specific trichomes contributing to the highly specialized trapping devices. *Investigations were carried out on six Mediterranean Aristolochia species. The morphology and arrangement of the trapping trichomes were investigated by scanning electron microscopy (SEM) and cryo-SEM. To demonstrate frictional anisotropy of the trapping trichome array, a microtribological approach was used. *The results of our experiments support a hypothesis long proposed, but never tested, regarding the trapping mechanism in proterogynous Aristolochia flowers: that an array of highly specialized trichomes arranged eccentrically to the underlying surface is responsible for the easy entrance of insects into flowers but impedes their escape. As they enter the male stage of anthesis, flowers significantly modify their inner surface characteristics, allowing insects to leave. *We have demonstrated the substantial contribution of trapping trichomes to the capture, retention and release of pollinators, an important prerequisite for making cross-pollination possible in most Aristolochia species. Finally, we compare trapping trichomes of Aristolochia with similar structures found in other trapping flowers as well as in pitchers of carnivorous plants not optimized for insect release.

The betrayed thief – the extraordinary strategy of Aristolochia rotunda to deceive its pollinators

Pollination of several angiosperms is based on deceit. In such systems, the flowers advertise a reward that ultimately is not provided. We report on a previously unknown pollination/mimicry system discovered in deceptive Aristolochia rotunda (Aristolochiaceae). Pollinators were collected in the natural habitat and identified. Flower scent and the volatiles of insects (models) potentially mimicked were analyzed by chemical analytical techniques. Electrophysiological and behavioral tests on the pollinators identified the components that mediate the plant–pollinator interaction and revealed the model of the mimicry system. The main pollinators of A. rotunda were female Chloropidae. They are food thieves that feed on secretions of true bugs (Miridae) while these are eaten by arthropod predators. Freshly killed mirids and Aristolochia flowers released the same scent components that chloropids use to find their food sources. Aristolochia exploits these components to deceive their chloropid pollinators. Aristolochia and other trap flowers were believed to lure saprophilous flies and mimic brood sites of pollinators. We demonstrate for A. rotunda, and hypothesize for other deceptive angiosperms, the evolution of a different, kleptomyiophilous pollination strategy. It involves scent mimicry and the exploitation of kleptoparasitic flies as pollinators. Our findings suggest a reconsideration of plants assumed to show sapromyiophilous pollination.

Detecting and Characterizing the Highly Divergent Plastid Genome of the Nonphotosynthetic Parasitic Plant Hydnora visseri (Hydnoraceae)

Plastid genomes of photosynthetic flowering plants are usually highly conserved in both structure and gene content. However, the plastomes of parasitic and mycoheterotrophic plants may be released from selective constraint due to the reduction or loss of photosynthetic ability. Here we present the greatly reduced and highly divergent, yet functional, plastome of the nonphotosynthetic holoparasite Hydnora visseri (Hydnoraceae, Piperales). The plastome is 27 kb in length, with 24 genes encoding ribosomal proteins, ribosomal RNAs, tRNAs, and a few nonbioenergetic genes, but no genes related to photosynthesis. The inverted repeat and the small single copy region are only approximately 1.5 kb, and intergenic regions have been drastically reduced. Despite extreme reduction, gene order and orientation are highly similar to the plastome of Piper cenocladum, a related photosynthetic plant in Piperales. Gene sequences in Hydnora are highly divergent and several complementary approaches using the highest possible sensitivity were required for identification and annotation of this plastome. Active transcription is detected for all of the protein-coding genes in the plastid genome, and one of two introns is appropriately spliced out of rps12 transcripts. The whole-genome shotgun read depth is 1,400× coverage for the plastome, whereas the mitochondrial genome is covered at 40× and the nuclear genome at 2×. Despite the extreme reduction of the genome and high sequence divergence, the presence of syntenic, long transcriptionally active open-reading frames with distant similarity to other plastid genomes and a high plastome stoichiometry relative to the mitochondrial and nuclear genomes suggests that the plastome remains functional in H. visseri. A four-stage model of gene reduction, including the potential for complete plastome loss, is proposed to account for the range of plastid genomes in nonphotosynthetic plants.

Escaping the lianoid habit: evolution of shrub-like growth forms in Aristolochia subgenus Isotrema (Aristolochiaceae)

UNLABELLED PREMISE OF THE STUDY A large range of growth forms is a notable aspect of angiosperm diversity and arguably a key element of their success. However, few studies within a phylogenetic context have explored how anatomical, developmental, and biomechanical traits are linked with growth form evolution. Aristolochia (∼500 species) consists predominantly of climbers, but a handful of shrub-like species are known from Aristolochia subgenus Isotrema (hereafter, shortened to Isotrema). We test hypotheses proposing that the establishment of functional traits linked to lianescence might limit the ability to evolve structurally diverse growth forms, particularly self-supporting forms. • METHODS We focus on the origin of the shrub habit in Isotrema, from which we sampled representatives from climbing to self-supporting forms. Morphological, anatomical, and biomechanical characters are optimized on a chloroplast- and nuclear-derived phylogeny. • KEY RESULTS Character-state reconstructions revealed that the climbing habit is plesiomorphic in Isotrema and shrub-like forms are derived from climbers. However, shrubs do not constitute a monophyletic group. Both shrubs and climbers show large multiseriate rays, but differ in terms of vessel size and proportion of fibers and soft tissues. • CONCLUSION We suggest that while shrub-like species might have partly escaped from the constraints of life as lianas; their height size and stability are not typical of self-supporting shrubs and trees. Shrubs retained lianoid stem characters that are known to promote flexibility such as ray parenchyma. The transitions to a shrub-like form likely involved relatively simple, developmental changes that may be attributed to heterochronic processes.

Growth Form Evolution in Piperales and Its Relevance for Understanding Angiosperm Diversification: An Integrative Approach Combining Plant Architecture, Anatomy, and Biomechanics

A striking feature of early angiosperm lineages is the variety of life forms and growth forms, which ranges from herbs, aquatic herbs, climbers, and epiphytes to woody shrubs and trees. This morphological and anatomical diversity is arguably one of the factors explaining how angiosperms dominate many ecosystems worldwide. However, just how such a wide spectrum of growth forms has evolved in angiosperms remains unclear. In this review, we investigate patterns of growth form diversification in Piperales, an early-diverging lineage (with stem age estimated at 201–128 Myr ago) and the most morphologically diverse clade among magnoliids. We outline patterns of growth form diversity and architecture as well as the biomechanical significance of developmental characters, such the organization, loss, and gain of woodiness. Asaroideae and Saururaceae are terrestrial as well as semiaquatic to aquatic herbaceous perennials bearing rhizomes. The Aristolochioideae and Piperaceae show higher levels of growth form diversity and biomechanical organization, with complex patterns of increasing or decreasing woodiness and architectural organization. The climbing habit has probably evolved independently in the Aristolochiaceae and Piperaceae, while mechanically unstable shrubs and, less frequently, treelets have evolved several times within these two most species-rich clades. A key developmental character underlying diversity in most Piperales—with the exception of the herbaceous Saruma (Asaroideae)—is the conserved development of the wood cylinder, in which fusiform initials are limited to fascicular cambial initials. The resulting large fraction of raylike tissue in the stem—a highly characteristic feature of woody species in the Piperales—potentially introduced mechanical constraints on the diversification of self-supporting architectures. This was possibly circumvented by the architectural development of repeated, large-diameter meristems in some shrublike habits via sympodial growth. Patterns of growth form evolution within Piperales potentially mirror some of the overall trends observed among early-diverging angiosperms as a whole as well as angiosperms in general. These include profound changes in life form and growth form linked to large-scale transitions in woodiness, diversity of mechanical organization, and shifts in architectural development.