ITS Polymorphisms Shed Light on Hybrid Evolution in Apomictic Plants: A Case Study on the Ranunculus auricomus Complex

The reconstruction of reticulate evolutionary histories in plants is still a major methodological challenge. Sequences of the ITS nrDNA are a popular marker to analyze hybrid relationships, but variation of this multicopy spacer region is affected by concerted evolution, high intraindividual polymorphism, and shifts in mode of reproduction. The relevance of changes in secondary structure is still under dispute. We aim to shed light on the extent of polymorphism within and between sexual species and their putative natural as well as synthetic hybrid derivatives in the Ranunculus auricomus complex to test morphology-based hypotheses of hybrid origin and parentage of taxa. We employed direct sequencing of ITS nrDNA from 68 individuals representing three sexuals, their synthetic hybrids and one sympatric natural apomict, as well as cloning of ITS copies in four representative individuals, RNA secondary structure analysis, and landmark geometric morphometric analysis on leaves. Phylogenetic network analyses indicate additivity of parental ITS variants in both synthetic and natural hybrids. The triploid synthetic hybrids are genetically much closer to their maternal progenitors, probably due to ploidy dosage effects, although exhibiting a paternal-like leaf morphology. The natural hybrids are genetically and morphologically closer to the putative paternal progenitor species. Secondary structures of ITS1-5.8S-ITS2 were rather conserved in all taxa. The observed similarities in ITS polymorphisms suggest that the natural apomict R. variabilis is an ancient hybrid of the diploid sexual species R. notabilis and the sexual species R. cassubicifolius. The additivity pattern shared by R. variabilis and the synthetic hybrids supports an evolutionary and biogeographical scenario that R. variabilis originated from ancient hybridization. Concerted evolution of ITS copies in R. variabilis is incomplete, probably due to a shift to asexual reproduction. Under the condition of comprehensive inter- and intraspecific sampling, ITS polymorphisms are powerful for elucidating reticulate evolutionary histories.     

Taxonomic separation ofKengyilia (Poaceae: Triticeae) in relation to nearest relatedRoegneria,Elymus, andAgropyron,based on some morphological characters

Based on 100 species representative of the four genera, we scored 290 herbarium specimens for a number of morphological characters. The data were subjected to canonical discriminant analysis using characters different from those in the identification key to these genera byBaum, Yen, andYang (1991). These characters collectively support the four groupsAgropyron, Kengyilia, Roegneria, andElymus as previously defined. The four groups are also supported by the linear discriminant function with an overall rate of 83% correct classification. Length of lemma awn was found to be an additional diagnostic character asAgropyron andKengyilia have lemma awns shorter than 5 mm, whereasRoegneria andElymus have longer lemma awns with very few exceptions. Length of glume awns is also a useful supplementary generic diagnostic.Agropyron andElymus have glume awns, whereas the majority of species ofKengyilia and more than half of the species ofRoegneria lack them. If a glume awn is present it is usually not longer than 1 mm.     

Phylogenetic analysis of <Emphasis Type="Italic">Kengyilia</Emphasis> species based on nuclear ribosomal DNA internal transcribed spacer sequences

Phylogenetic analysis was conducted based on sequences of the internal transcribed spacer region (ITS) of nuclear ribosomal DNA in 17 species of Kengyilia, together with those of 18 species from Pseudoroegneria, Agropyron, Roegneria and Douglasdeweya by the maximum parsimony, maximum likelihood and neighbor-joining distance methods. The results indicate that species of Kengyilia had close affinities to species of Douglasdeweya and Agropyron. The species in Kengyilia was identified as two subgroups with regard to geographic distribution, indicating that species from the same distribution had a closer phylogenetic relationship. The genus Kengyilia was found as a ligament-group between Roegneria and Agropyron. The ITS sequence is a useful tool for studying the phylogeny of closely related species.     

Morphological,cytological, and molecular evidences for natural hybridization between Roegneria stricta and Roegneria turczaninovii (Triticeae: Poaceae)

Some plants with low fertility are morphologically intermediate between Roegneria stricta and Roegneria turczaninovii, and were suspected to be natural hybrids between these species. In this study, karyotype analysis showed that natural hybrids and their putative parents were tetraploids (2n = 4x = 28). Meiotic pairing in natural hybrids is more irregular than its putative parents. Results of genomic in situ hybridization and fluorescence in situ hybridization indicate that natural hybrids contain the same genome as their putative parents. The nuclear gene DNA meiotic recombinase 1 (DMC1) and the chloroplast gene rps16 of natural hybrids and their putative parents were analyzed for evidence of hybridization. The results from molecular data supported by morphology and cytology demonstrated that the plants represent natural hybrids between R. stricta and R. turczaninovii. The study is important for understanding species evolution in the genus since it demonstrates for the first time the existence of populations of natural homoploid hybrids in Roegneria. The study also reports for the first time that the composition of the genomic formula of R. turczaninovii is StY, confirming that the current taxonomic status is correct.     

Polymorphic Sites in ITS1-5.8S rDNA-ITS2 Region in Hybridogenic Genus × <Emphasis Type="Italic">Elyhordeum</Emphasis> and Putative Interspecific Hybrids <Emphasis Type="Italic">Elymus</Emphasis> (Poaceae: Triticeae)

The genus Elymus L. is a complicated aggregate of ecological and geographical races, species, subspecies, varieties, and hybrids. We suggest that comparative analysis of intragenomic polymorphism of internal transcribed spacers ITS1 and ITS2 of 35S rRNA genes in the supposed hybrids and their possible “parents” can be one of the approaches to verification of hybrid origin of the samples collected in nature to confirm or reject the hypotheses about their possible “parents.” Polymorphic sites (PS) in ITS of 23 Elymus species, as well as in two supposed interspecific Elymus hybrids and in a supposed intergeneric hybrid between Elymus × Hordeum determined as × Elyhordeum sp., were analyzed in the work. We collected all hybrids in the Altai. There were 2 and 5 PS in two samples of E. dahuricus and 1 and 4 PS in two studied samples of E. schrenkianus in the ITS1-5.8S rDNA-ITS2 region. From 0 to 4 (modes 0 and 3) PS were detected in 32 samples relating to 21 tetraploid Elymus species. More PS (14) were found in the × Elyhordeum sp. sample. A large number of single nucleotide substitutions were found in 5.8S rRNA in × Elyhordeum. It was shown that about half of them do not change the secondary structure of the 5.8S rRNA molecule, so these molecules probably retain the ability to work as a component of large subunit of a ribosome. On the other hand, the absence or weakening of 5.8S rDNA homogenization in × Elyhordeum indirectly suggests that a significant part of 5.8S rDNA is not transcribed. Paradoxically, ITS sequences of × Elyhordeum sp. are less polymorphic than 5.8S rDNA. There are no ITS sequences derived from Hordeum among × Elyhordeum ITS sequenced by Sanger method. No traces of the H subgenome and a subgenome originating from Agropyron (P-subgenome) are seen in the Alt 10–278 plant genome (a chimera, combining the morphological traits of Elymus, Elytrigia, and Agropyron). In this plant, as well as in the supposed intersectional hybrid Alt 11–60 distinguished by a mosaic of the traits typical for the E. caninus × E. mutabilis species, only 4 and 5 PS, respectively, are detected when sequencing by Sanger method. The comparison of ITS sequences of the supposed Elymus Alt 10–278 hybrid and its probable “parents” demonstrates that one of the species of the Elymus macrourus kinship circle, as well as the Elytrigia geniculata, could be one of its ancestors. The comparison of the ITS sequence of the supposed parental species with ITS of Alt 11–60 samples and five PS of the supposed Alt 11–60 hybrid does not contradict the hypothesis that this is an intersectional hybrid of the first generation that emerged with the involvement of E. caninus and E. mutabilis common in the Altai.     

Phylogenetic relationships among the species of <Emphasis Type="Italic">Elymus</Emphasis> sensu lato in Triticeae (Poaceae) based on nuclear rDNA ITS sequences

The genus Elymus L. sensu lato includes Roegneria, Elymus, Hystrix, Sitanion and Kengyilia, and they are very important group in the tribe Triticeae. However, the phylogenetic relationships and taxonomic status of them are still in dispute. The ITS sequences were obtained and analyzed for their phylogenetic relationships by using Maximum Parsimony (MP) and Bayesian Inference (BI) methods. The main results were as follows: (1) Most species in Roegneria, Elymus and Sitanion were clustered in the St clade with diploid St genome species, and it was difficult to distinguish the species in Roegneria and Elymus; (2) The polyploid species with St genomes in the St clade were divided into three groups, which suggests that there exists differentiation of St genome in polyploids; (3) Most species of Kengyilia have only P-type of clone and clustered with diploid Agropyron species, which may suggest that Kengyilia is a valid genus; (4) Hy. patula, the type species of Hystrix was clustered with species of Elymus, while Hy. duthiei ssp. duthiei, Hy. duthiei ssp. longearistata, Hy. coreana and Hy. komarovii were grouped with diploid Psathyrostachys species. It indicated that Hy. patula is distinct related to other Hystrix species, and it is reasonable to treat Hystrix patula as Elymus hystrix and other species in Hystrix should be transferred to Leymus; (5) The “clones bias” in ITS sequences are widespread in the allopolyploid species. The article is published in the original.     

Examination of the hybrid origin of the wild potato Solanum ruiz-lealii Brücher

The common potato, tetraploid Solanum tuberosum spp. tuberosum L. (tbr), has a narrow genetic base but a large number of related tuber-bearing species that harbor genetic diversity for agronomic characters. The taxonomic status of Solanum ruiz-lealii Brücher (rzl), a diploid species endemic to Mendoza province, Argentina, is controversial. It has been described as a new species of non-hybrid origin and as a natural hybrid between S. kurtzianum Bitt. & Wittm. (ktz) and S. chacoense Bitt. (chc). The hypothesis of the hybrid origin of rzl is examined systematically for the first time by phenetic analyses of morphological and molecular (SSR markers) data, and cytological analyses of interspecific hybrids. The morphological, cytological and molecular data are congruent, and suggest that rzl is not a recent natural hybrid between the ktz and the chc populations studied but has probably originated by divergence of chc, or by hybridization between chc and another taxon.     

Hybridization between insular endemic and widespread species of Viola in non-disturbed environments assessed by nuclear ribosomal and cpDNA sequences

Viola jaubertiana Marès & Vigin. is a narrow endemic violet of the Balearic Islands, restricted to small, fragmented, and scattered populations living in inaccessible rocky places and calcareous overhangs. V. jaubertiana is entirely glabrous and morphologically very uniform. However, several authors have reported hairy individuals collected at the type locality, suggesting that these rupicolous, pubescent plants are putative hybrids with V. alba Bess. subsp. dehnhardtii (Ten.) W. Becker, a woodland violet growing in the area. Ribosomal ITS sequences of the putative hybrids analysed showed additive species-specific sites of V. alba subsp. dehnhardtii and V. jaubertiana, strongly supporting its hybrid origin from these progenitors. CpDNA sequences of all putative hybrids were uniform, and identical to those present in V. jaubertiana accessions. This suggests that the gene flow between V. alba subsp. dehnhardtii and V. jaubertiana is unidirectional and identifies the endemic V. jaubertiana as the unique ovule donor. The additivity of the ITS sequences, together with the pollen and ovule sterility, suggests that the sampled individuals are primary F₁ hybrids, whereas no trace of introgressive hybridization or hybrid zone has been evidenced by the nuclear and plastid markers used. Judging from herbarium sheets, hybridization between V. alba subsp. dehnhardtii and V. jaubertiana is recurrent and dates back from the XIXth century. Hybrids between these species are not linked to disturbed environments. In fact, they have been always reported in rupicolous habitats, where the maternal species is restricted.     

Natural Hybridization and Introgression between Ligularia cymbulifera and L. tongolensis (Asteraceae,Senecioneae) in Four Different Locations

Natural hybridization has been considered to represent an important factor influencing the high diversity of the genus Ligularia Cass. in the Hengduan Mountains, China. Natural hybridization has been confirmed to occur frequently in Ligularia. To date, however, it has been demonstrated only within a single population. In this paper, we present evidence of natural hybridization in Ligularia from four different locations. The internal transcribed spacer (ITS) region of the nuclear ribosomal DNA and three chloroplast intergenic spacers (trnK-rps16, trnL-rpl32 and trnQ-5''rps16) of 149 accessions of putative hybrids and their putative parents (L. cymbulifera and L. tongolensis) were analyzed for evidence of hybridization. The ITS data clearly distinguished two putative parental species and sympatric L. vellerea and supported the hypothesis that those morphological intermediates were products of natural hybridization between L. cymbulifera and L. tongolensis. Moreover, several identified morphological parents were actual introgressed products. Because of hybridization and introgression, chloroplast DNA sequences generated a poorly resolved network. The present results indicate that varying degrees of hybridization and introgression occur differently depending on the habitat context. We conclude that gene flow caused by natural hybridization in Ligularia indeed plays an important role in the species diversity.     

Phylogeny and maternal donor of Kengyilia (Triticeae: Poaceae) based on chloroplast trnT–trnL sequences

The chloroplast DNA regions trnT–trnL was used to analyze to phylogenetic relationships and maternal donor of Kengyilia species and their closely related species. The Neighbor-Joining phylogenetic reconstructions partitioned the species into two reciprocally monophyletic groups. Kengyilia melanthera was related to species of Agropyron, whereas the other species were related to species of Pseudoroegneria and Roegneria. These results indicate that there have been at least two phylogenetically divergent maternal donors within Kengyilia, i.e. Agropyron (P genome) and Pseudoroegneria (St genome). In addition, the St genome of Kengyilia had several origins and diverse species of Pseudoroegneria might have taken part in the formation of polyploid species of Kengyilia.     

Distinct origin of the Y and St genome in Elymus species: evidence from the analysis of a large sample of St genome species using two nuclear genes

Background

Previous cytological and single copy nuclear genes data suggested the St and Y genome in the StY-genomic Elymus species originated from different donors: the St from a diploid species in Pseudoroegneria and the Y from an unknown diploid species, which are now extinct or undiscovered. However, ITS data suggested that the Y and St genome shared the same progenitor although rather few St genome species were studied. In a recent analysis of many samples of St genome species Pseudoroegneria spicata (Pursh) À. Löve suggested that one accession of P. spicata species was the most likely donor of the Y genome. The present study tested whether intraspecific variation during sampling could affect the outcome of analyses to determining the origin of Y genome in allotetraploid StY species. We also explored the evolutionary dynamics of these species.

Methodology/Principal Findings

Two single copy nuclear genes, the second largest subunit of RNA polymerase II (RPB2) and the translation elongation factor G (EF-G) sequences from 58 accessions of Pseudoroegneria and Elymus species, together with those from Hordeum (H), Agropyron (P), Australopyrum (W), Lophopyrum (E^e), Thinopyrum (E^a), Thinopyrum (E^b), and Dasypyrum (V) were analyzed using maximum parsimony, maximum likelihood and Bayesian methods. Sequence comparisons among all these genomes revealed that the St and Y genomes are relatively dissimilar. Extensive sequence variations have been detected not only between the sequences from St and Y genome, but also among the sequences from diploid St genome species. Phylogenetic analyses separated the Y sequences from the St sequences.

Conclusions/Significance

Our results confirmed that St and Y genome in Elymus species have originated from different donors, and demonstrated that intraspecific variation does not affect the identification of genome origin in polyploids. Moreover, sequence data showed evidence to support the suggestion of the genome convergent evolution in allopolyploid StY genome species.     

Molecular tests of the proposed diploid hybrid originof Gilia achilleifolia (Polemoniaceae)

Gilia achilleifolia is a putative diploid hybrid species. Hybrid origin was hypothesized based on traditional biosystematicevidence (i.e., morphological, cytological, and crossability data),which may be insufficient to establish genealogical history. Here,phylogenetic analysis of sequence data from the internal transcribedspacer (ITS) regions is used to examine the relationship between theputative hybrid species and its proposed parents. Isozyme variation isassayed to test for genetic additivity in the putative hybrid taxon andmorphological data are analyzed cladistically to evaluate the charactersthat led to the original hypothesis of hybrid origin. The ITS-basedgene tree placed G. achilleifolia in two divergent clades, eachsister to one of the putative parental lineages. Little isozymeadditivity was observed and G. achilleifolia possessed sixunique alleles among 42 alleles observed. However, ITS and isozymetrees differed in their placement of the two lineages of G.achilleifolia; both lineages are closer to a third putative parentin the isozyme tree. Also, G. achilleifolia is intermediate orpolymorphic for all nine morphological characteristics differentiatingthe parental species. Sorting of ancestral polymorphisms cannot easilyaccount for expression patterns of seven of these characters. In ourview, these results fail to distinguish between alternative hypothesesof ancient hybrid origin and divergent evolution, belying the difficultyof detecting ancient hybrids.     

Untangling Nucleotide Diversity and Evolution of the H Genome in Polyploid Hordeum and Elymus Species Based on the Single Copy of Nuclear Gene DMC1

Numerous hybrid and polypoid species are found within the Triticeae. It has been suggested that the H subgenome of allopolyploid Elymus (wheatgrass) species originated from diploid Hordeum (barley) species, but the role of hybridization between polyploid Elymus and Hordeum has not been studied. It is not clear whether gene flow across polyploid Hordeum and Elymus species has occurred following polyploid speciation. Answering these questions will provide new insights into the formation of these polyploid species, and the potential role of gene flow among polyploid species during polyploid evolution. In order to address these questions, disrupted meiotic cDNA1 (DMC1) data from the allopolyploid StH Elymus are analyzed together with diploid and polyploid Hordeum species. Phylogenetic analysis revealed that the H copies of DMC1 sequence in some Elymus are very close to the H copies of DMC1 sequence in some polyploid Hordeum species, indicating either that the H genome in theses Elymus and polyploid Hordeum species originated from same diploid donor or that gene flow has occurred among them. Our analysis also suggested that the H genomes in Elymus species originated from limited gene pool, while H genomes in Hordeum polyploids have originated from broad gene pools. Nucleotide diversity (π) of the DMC1 sequences on H genome from polyploid species (π = 0.02083 in Elymus, π = 0.01680 in polyploid Hordeum) is higher than that in diploid Hordeum (π = 0.01488). The estimates of Tajima''s D were significantly departure from the equilibrium neutral model at this locus in diploid Hordeum species (P<0.05), suggesting an excess of rare variants in diploid species which may not contribute to the origination of polyploids. Nucleotide diversity (π) of the DMC1 sequences in Elymus polyploid species (π = 0.02083) is higher than that in polyploid Hordeum (π = 0.01680), suggesting that the degree of relationships between two parents of a polyploid might be a factor affecting nucleotide diversity in allopolyploids.     

Different maternal genome donor to Kengyilia species inferred from chloroplast trnL-F sequences

To reveal the maternal donor of species in genus Kengyilia, the chloroplast trnL-F sequences of 14 Kengyilia species and several related diploid species were analyzed by using Maximum Parsimony (MP) and Bayesian Inference (BI) methods. The species in Kengyilia were clustered in different clades, which indicated that Agropyron (P) is the likely maternal genome donor to Kengyilia melanthera, K. mutica and K. thoroldiana, while the maternal donor to Kengyilia batalinii, K. nana, K. kokonorica, K. kaschgarica, K. hirsuta, K. alatavica, K. gobicola, K. zhaosuensis, K. rigidula, K. longiglumis and K. grandiglumis was St or Y Roegneria genome.     

SYNTHETIC AGROPYRON-ELYMUS HYBRIDS. I. ELYMUS CANADENSIS × AGROPYRON SUBSECUNDUM

Twenty-four seeds were formed in 34 hand-emasculated E. canadensis florets exposed to A. subsecundum pollen. Fifteen of the 24 seeds germinated, and 12 plants were raised to maturity. Each of the 12 plants proved to be a hybrid. The hybrids were morphologically intermediate between the parents, although they favored A. subsecundum in general appearance. The parent plants were meiotically regular and behaved cytologically as strict allotetraploids, 2n = 28. Fourteen bivalents were formed in 12.6% of the hybrid cells interpreted at metaphase I. All other hybrid cells contained various combinations of univalents, bivalents, and multivalents. Mean chromosome associations of 0.22 univalents, 11.70 bivalents, 0.11 trivalente, 0.23 quadrivalents, 0.01 pentavalents, and 0.55 hexavalents were observed in 135 hybrid cells. All hybrid pollen examined was shriveled and non-staining. Five hybrids produced eight seeds, and seven hybrids were completely sterile. The ready cross-compatibility of E. canadensis and A. subsecundum and the relatively good chromosome pairing in their hybrids suggest a much closer relationship between the parent species than is implied by the prevailing taxonomic treatment. Structural rearrangements appear to be responsible for the relatively few differences between E. canadensis and A. subsecundum genomes and for the sterility of the hybrids. Cytological data from this and other investigations indicate a close relationship between many self-fertilizing Agropyron, Elymus, and Sitanion species. It is postulated that this composite of self-fertilizing Agropyron, Elymus, and Sitanion species originated by hybridization between A. spicatum and an unidentified Hordeum species.     

Natural hybridization and introgression among sympatrically distributed Rhododendron species in Guizhou,China

Natural hybridizations occur among Rhododendron delavayi, R. decorum and R. irroratum, however, there was little study that had addressed the interbreeding behaviors when the three species grew in the same geographic areas. In this study, 37 accessions, containing the three species and the putative hybrids, were obtained from Baili Rhododendron Nature Reserve, Guizhou, China. Examinations of hybridization patterns with AFLP markers have led to a total of 107 diagnostic DNA fragments, which were analyzed with Principal Co-ordinate, Structure and NewHybirds analyses. The data confirmed that the existence of hybrids originated from the interbreeding between R. delavayi and R. irroratum in Baili Rhododendron Nature Reserve. R. decorum did not appear to be involved in the hybridization. Furthermore, most hybrids detected were a result of backcrossing, indicating that this hybrid differed from F1 dominant hybrids between R. delavayi and R. irroratum found in previous studies.     

Molecular evidence for repeated hybridization events involved in the origin of the genus × Crepidiastrixeris (Asteraceae) using RAPDs and ITS data

We investigated the hybrid origin of × Crepidiastrixeris denticulato-platyphylla using RAPDs and ITS sequence data. The putative parents Paraixeris denticulata and Crepidiastrum platyphyllum represent separate species, irrespective of geographical origin. The occurrence of species specific RAPD markers from P. denticulata and C. platyphyllum in × C. denticulato-platyphylla established unambiguously a hybrid origin between the two taxa. This was in line with the occurrence of a combination of morphological characters such as plant habit and floret numbers. The parent taxa differed from each other by 7 nucleotide substitutions and 2 indel events in the ITS region. The hybrids showed sequence additivity and most likely represent F₁ plants, with the exception of two plants which were of possible F₂ origin, possessing either the ITS sequences of one parent only, or one predominant ITS type. The hybrids occurred in two out of three localities where the parents occurred sympatrically. This fact, together with the short life-span of the plants, suggests that × C. denticulato-platyphylla exists as a result of repeated, frequent hybridization between the parent species.  © 2006 The Linnean Society of London, Botanical Journal of the Linnean Society , 2006, 151 , 333–343.     

Microsatellite analyses of artificial and spontaneous dogrose hybrids reveal the hybridogenic origin of Rosa micrantha by the contribution of unreduced gametes

Dogroses are characterized by a unique meiosis system, the so-called canina meiosis, which facilitates sexual reproduction at odd-number ploidy. The mostly pentaploid somatic level of dogroses is restored by a merger of haploid sperm cells and tetraploid egg cells. We analyzed experimental hybrids between different dogrose species using microsatellites to determine pollen-transmitted alleles. This information was used to reconstruct the putative hybridogenic origin of Rosa micrantha and R. dumalis and to estimate the frequency of spontaneous hybridization in a natural population. We found no evidence for the hybrid origin of R. dumalis, but our data suggest that R. micrantha presumably arose by hybridization between R. rubiginosa and R. canina or R. corymbifera. We observed only hexaploid individuals of R. micrantha, thus the establishment of this hybridogenic species was favored when unreduced gametes contributed to their origin. We demonstrate that spontaneous hybrids originated infrequently from the parental species in a natural population, but hybridization was often associated with the formation of unreduced gametes. We postulate that unreduced gametes play a major role in the evolutionary success of dogrose hybrids because they provide highly homologous chromosomes crucial for bivalent formation during canina meiosis and thus ensuring this unique form of sexual reproduction.     

Nuclear and chloroplast DNA sequences data support the origin of Potamogeton intortusifolius J.B. He in China as a hybrid between P. perfoliatus Linn. and P. wrightii Morong

Internal transcribed spacers (ITS) of nuclear ribosomal DNA and chloroplast rbcL gene sequence data were used to test the hypothesis that natural populations of Potamogeton intortusifolius J.B. He in China originated from hybridization between P. perfoliatus Linn. and P. wrightii Morong. Based on ITS sequences data, P. intortusifolius possessed heterozygous rDNA genotypes which confirmed the hybrid origin of P. intortusifolius. Chloroplast rbcL gene sequences of P. intortusifolius from Yichang population revealed the same chloroplast haplotype as P. perfoliatus and the samples of P. intortusifolius from Weinan population had the same chloroplast haplotype as P. wrightii, which indicated that both putative parental species had been the maternal parent and that the two populations of P. intortusifolius had independent origins. This study confirms P. intortusifolius as a reciprocal hybrid. Because P. × intortusifolius in China has the same hybrid origin as P. × anguillanus Koidz. in Japan, it is suggested that P. × intortusifolius should be a synonym of P. × anguillanus.     

New evidence for a postglacial homoploid hybrid origin of the widespread Central European Scabiosa columbaria L. s. str. (Dipsacaceae)

We have tested whether Scabiosa columbaria s. str. could have originated by recent homoploid hybrid speciation because it is of intermediate morphology and is distributed in areas under glacial influence. Existing morphological and new RAPD data for 11 ingroup populations were analysed using multivariate statistics. Most methods indicated that S. columbaria s. str. could be the first example for a homoploid hybrid origin from Central Europe although a rigorous proof was missing partly because of ongoing introgression. Sequence variation was absent for 5,000 bp from 11 regions supporting a postglacial origin of S. columbaria s. str. An analysis of realized macroclimatic niches using GIS data showed that the niches of S. columbaria s. str. were partly intermediate between its putative parental species rather than extreme as often found in other homoploid hybrids. This could be due to geographical preconditions: large new habitats were available in postglacial Europe while in the case of most other homoploid hybrids only ecologically challenging habitats were not occupied by parental taxa.