Towards resolving the Knautia arvensis agg. (Dipsacaceae) puzzle: primary and secondary contact zones and ploidy segregation at landscape and microgeographic scales

Kolář, Filip; Štech, Milan; Trávníček, Pavel; Rauchová, Jana; Urfus, Tomáš; Vít, Petr; Kubešová, Magdalena; Suda, Jan

doi:10.1093/aob/mcp016

Cited by 116 publications

(132 citation statements)

References 48 publications

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“…(Dipsacaceae) is a common perennial herb, inhabiting dry and mesophilous meadows, pastures, shrublands, open woods, forest margins and roadsides throughout most of Europe (Štěpánek 1997). It harbours two more-or-less spatially separated (parapatric) but morphologically only weakly differentiated ploidy levels, diploid and tetraploid, which are sometimes treated as separate subspecies or varieties (Kaplan 1998;Kolář et al 2009). Knautia arvensis was selected as a good model system for studying the role of AM symbiosis in plant adaptation to serpentine conditions because: (1) it is a mycorrhizal species (Wang and Qiu 2006); (2) it inhabits both serpentine and non-serpentine substrates in Central Europe (Kaplan 1998); and (3) the serpentine populations (ecotypes) showed higher tolerance to elevated Mg concentrations (lower Ca/Mg ratio) in a hydroponic experiment than the non-serpentine populations (F. Kolář et al, unpublished data).…”

Section: The Plant Species Under Studymentioning

confidence: 99%

“…Knautia arvensis was selected as a good model system for studying the role of AM symbiosis in plant adaptation to serpentine conditions because: (1) it is a mycorrhizal species (Wang and Qiu 2006); (2) it inhabits both serpentine and non-serpentine substrates in Central Europe (Kaplan 1998); and (3) the serpentine populations (ecotypes) showed higher tolerance to elevated Mg concentrations (lower Ca/Mg ratio) in a hydroponic experiment than the non-serpentine populations (F. Kolář et al, unpublished data). Furthermore, both diploid and tetraploid cytotypes occur on serpentine as well as on non-serpentine sites (Kolář et al 2009), thus providing an opportunity for assessment of the interactions between mycorrhizal inoculation and genome copy number by comparison of plants of different ploidy level within the same species.…”

Section: The Plant Species Under Studymentioning

confidence: 99%

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Arbuscular mycorrhizal symbiosis on serpentine soils: the effect of native fungal communities on different Knautia arvensis ecotypes

2011

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Serpentine soils represent a unique environment that imposes multiple stresses on vegetation (low Ca/Mg ratios, macronutrient deficiencies, elevated heavy metal concentrations and drought). Under these conditions, a substantial role of arbuscular mycorrhizal (AM) symbiosis can be anticipated due to its importance for plant nutrition and stress alleviation. We tested whether serpentine and non-serpentine populations of Knautia arvensis (Dipsacaceae) differ in the benefits derived from native AM fungal communities. Four serpentine and four non-serpentine populations were characterised in terms of mycorrhizal colonisation and soil characteristics. The serpentine populations showed significantly lower mycorrhizal colonisation than their non-serpentine counterparts. The mycorrhizal colonisation positively correlated with soil pH, Ca and K concentrations and Ca/Mg ratio. Seedlings from each population were then grown for 3 months in their sterilised native substrates, either uninoculated or reinoculated with native AM fungi. Two serpentine and two non-serpentine populations responded positively to mycorrhizal inoculation, while no significant change in plant growth was observed in the remaining populations. Contrary to our hypothesis, serpentine populations of K. arvensis did not show higher mycorrhizal growth dependence than non-serpentine populations when grown in their native soils and inoculated with native AM fungi.

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Section: The Plant Species Under Studymentioning

confidence: 99%

Section: The Plant Species Under Studymentioning

confidence: 99%

Arbuscular mycorrhizal symbiosis on serpentine soils: the effect of native fungal communities on different Knautia arvensis ecotypes

2011

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“…A diverse array of breeding barriers can mediate assortative mating in natural populations, including heterogeneity in the spatial distribution of cytotypes (van Dijk et al 1992;Husband and Schemske 1998;Kolař et al 2009) due to different microhabitat preferences (Felber-Girard et al 1996); temporal isolation due to shifts in flowering phenologies (Petit et al 1997;Marques et al 2007;Jersáková et al 2010); mechanical isolation due to differences in floral morphology (reviewed in Grant 1994); segregation resulting from divergent behaviors and preferences of pollinators (Grant 1994;Thompson et al 2004;Marques et al 2007; Thompson and Merg 2008); gametic isolation (Husband et al 2002;Mráz 2003;Brock 2004); and/or reduced fitness or sterility of the hybrids (Ramsey and Schemske 1998;Buggs and Pannell 2006;Prentis et al 2007). All together, such breeding barriers will act in concert and govern the levels of pollen flow between cytotypes, thereby determining the cytotype composition of the offspring and population.…”

Section: Introductionmentioning

confidence: 99%

Breeding barriers at a diploid–hexaploid contact zone in Aster amellus

et al. 2010

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Polyploidization is an important mechanism of sympatric speciation, but few studies have addressed breeding barriers between polyploids and their diploid progenitors in the field, and the available data have been mainly obtained from diploid-tetraploid contact zones. In contrast to diploid-tetraploid complexes, hybridization between diploid and hexaploid individuals may lead to viable fertile tetraploid offspring, and thus the interactions between these ploidy levels can be more complex. We investigated the breeding barriers operating between diploid and hexaploid individuals of Aster amellus at a contact zone in Central Europe to understand the absence of hybrids (i.e., tetraploids) and mixed populations. Phenological segregation, assortative mating mediated by pollinators and crossing ability were assessed under natural and controlled conditions in diploid and hexaploid populations growing in close proximity. The results revealed low levels of reproductive isolation (RI) due to flowering phenology (RI = 11-45%) and pollinator behavior (RI = 17%), so that pollen transfer between diploids and hexaploids is possible. In contrast, almost complete reproductive isolation was observed due to a series of postpollination barriers that significantly reduced the production of offspring from inter-cytotype crosses (RI = 99.9%), even though some tetraploids were detected in seeds and seedlings. We conclude that the absence of tetraploids at the contact zone is probably due Electronic supplementary material The online version of this article (to a combination of several factors, including spatial segregation, strong post-pollination barriers (such as gametic isolation, low viability of tetraploid seeds and/or inability of tetraploid plants to reach the flowering stage), and to a lesser extent, temporal and behavioral segregation. Future studies should explore the fitness of tetraploids and the effect of different traits on the reproductive success and fitness of each cytotype. This will enable a fuller understanding of the dynamics and mechanisms acting in contact zones.

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“…Variation in chromosome numbers in genus Lantana encourages the use of genome size as a species-specific marker. Genome size has been well-applied to resolve notable species complexes such as Reynoutria (Mandák et al 2003); Knautia arvensis (Kolář et al 2009); Dryopteris carthusiana (Ekrt et al 2010); Callitriche (Prančl et al 2014) and, identification of invasive alien taxa (see Suda et al 2010). Further, documentation of population cytotype structure of the invasive genets and their geographical distribution is central to monitor complex constituents' invasion potential.…”

Section: Future Directionsmentioning

confidence: 99%

Lantana camara L. (sensu lato): an enigmatic complex

Goyal¹,

Sharma²

2015

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Lantana camara L., considered among the world's worst invaders is in identity crisis and contentiously referred as Lantana camara L. (sensu lato). Taxonomic ambiguity in L. camara L. (sensu lato), a species complex is one of the grim caveats behind incompetence of its management efforts. Recognizing the extent of variability within the complex, we aim to highlight the need to circumscribe its composition to bring effective management and control efforts into practice. There is a need for clear terminology to examine weedy, naturalized and/or invasive complex constituents that have been placed under the contentious umbrella of 'L. camara L. (sensu lato)'. The time is ripe for invasion ecologists, cytogeneticists and conservationists to collaboratively focus on disentangling the complex and integrate their knowledge and expertise into management and control programs.

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Towards resolving the Knautia arvensis agg. (Dipsacaceae) puzzle: primary and secondary contact zones and ploidy segregation at landscape and microgeographic scales

Cited by 116 publications

References 48 publications

Arbuscular mycorrhizal symbiosis on serpentine soils: the effect of native fungal communities on different Knautia arvensis ecotypes

Arbuscular mycorrhizal symbiosis on serpentine soils: the effect of native fungal communities on different Knautia arvensis ecotypes

Breeding barriers at a diploid–hexaploid contact zone in Aster amellus

Lantana camara L. (sensu lato): an enigmatic complex

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