TY  - JOUR
A1  - Lauterbach, Dirk
A1  - Ristow, Michael
A1  - Gemeinholzer, B.
T1  - Genetic population structure, fitness variation and the importance of population history in remnant populations of the endangered plant Silene chlorantha (Willd.) Ehrh. (Caryophyllaceae)
JF  - Plant biology
N2  - Habitat fragmentation can lead to a decline of genetic diversity, a potential risk for the survival of natural populations. Fragmented populations can become highly differentiated due to reduced gene flow and genetic drift. A decline in number of individuals can result in lower reproductive fitness due to inbreeding effects. We investigated genetic variation within and between 11 populations of the rare and endangered plant Silene chlorantha in northeastern Germany to support conservation strategies. Genetic diversity was evaluated using AFLP techniques and the results were correlated to fitness traits. Fitness evaluation in nature and in a common garden approach was conducted. Our analysis revealed population differentiation was high and within population genetic diversity was intermediate. A clear population structure was supported by a Bayesian approach, AMOVA and neighbour-joining analysis. No correlation between genetic and geographic distance was found. Our results indicate that patterns of population differentiation were mainly caused by temporal and/or spatial isolation and genetic drift. The fitness evaluation revealed that pollinator limitation and habitat quality seem, at present, to be more important to reproductive fitness than genetic diversity by itself. Populations of S. chlorantha with low genetic diversity have the potential to increase in individual number if habitat conditions improve. This was detected in a single large population in the investigation area, which was formerly affected by bottleneck effects.
KW  - AFLP
KW  - fitness
KW  - population genetic structure
KW  - population history
Y1  - 2011
U6  - https://doi.org/10.1111/j.1438-8677.2010.00418.x
SN  - 1435-8603
VL  - 13
IS  - 4
SP  - 667
EP  - 677
PB  - Wiley-Blackwell
CY  - Hoboken
ER  - 
TY  - JOUR
A1  - Lauterbach, Daniel
A1  - Ristow, Michael
A1  - Gemeinholzer, Birgit
T1  - Population genetics and fitness in fragmented populations of the dioecious and endangered Silene otites (Caryophyllaceae)
JF  - Plant systematics and evolution
N2  - Population fragmentation is often correlated with loss of genetic diversity and reduced fitness. Obligate out-crossing (dioecy) is expected to enhance genetic diversity, reduce genetic differentiation, and avoid inbreeding depression through frequent gene flow. However, in highly fragmented populations dioecy has only diminishing effects upon genetic structure as pollination limitations (e.g. flight distance of pollinators) most often restrict inter-population gene flow in insect pollinated species. In fragmented dry grasslands in northeastern Germany, we analysed genetic structure, fitness, and habitat quality of the endangered dioecious Silene otites (Caryophyllaceae). Using AFLP markers, a high level of differentiation among ten populations was found (F (st) = 0.36), while the intra-population genetic diversities (H (E) = 0.165-0.240) were similar as compared to hermaphroditic species. There was neither a correlation between geographic and genetic distance nor between genetic diversity and population size, which indicates reduced gene flow among populations and random genetic drift. Plant size was positively correlated with genetic diversity. Seed set and number of juveniles were positively related to population size. Higher total coverage resulted in reduced plant fitness, and the number of juveniles was negatively correlated to cryptogam cover. Additionally, we found a sex ratio bias towards more male plants in larger populations. Overall, our results indicate that on a regional geographic scale dioecy does not necessarily prevent genetic erosion in the case of habitat fragmentation, especially in the absence of long distance seed and pollen dispersal capacity.
KW  - AFLP
KW  - Population size
KW  - Mating system
KW  - Isolation by distance
KW  - Sex ratio
Y1  - 2012
U6  - https://doi.org/10.1007/s00606-011-0533-0
SN  - 0378-2697
VL  - 298
IS  - 1
SP  - 155
EP  - 164
PB  - Springer
CY  - Wien
ER  - 
TY  - JOUR
A1  - Lauterbach, Daniel
A1  - Burkart, Michael
A1  - Gemeinholzer, Birgit
T1  - Rapid genetic differentiation between ex situ and their in situ source populations - an example of the endangered Silene otites (Caryophyllaceae)
JF  - Botanical journal of the Linnean Society
N2  - Ex situ cultivation in botanic gardens could be one possibility to preserve plant species diversity and genetic variation. However, old ex situ populations are often sparsely documented. We were able to retrieve three different ex situ populations and their source in situ populations of the endangered plant species Silene otites after 20-36 years of isolation. Furthermore, three additional wild populations were included in the analysis. Population genetic diversity and differentiation were analysed using AFLP markers. Genetic variation in the ex situ populations was lower than the variation found in the in situ populations. Strong differentiation (F-ST = 0.21-0.36) between corresponding in situ and ex situ populations was observed. Bayesian clustering approach also showed a distinct genetic separation between in situ and ex situ populations. The high genetic differentiation and loss of genetic diversity during spatial and temporal isolation in the ex situ populations can be attributable to small population sizes and unconscious selection during cultivation. Therefore, adequate sampling prior to ex situ cultivation and large effective population sizes are important to preserve genetic diversity. Near-natural cultivation allowing for generation overlap and interspecific competition without artificial selection is recommended as being best for the maintenance of the genetic constitution.
KW  - AFLP
KW  - botanical garden
KW  - conservation genetics
KW  - founder effect
KW  - population size
Y1  - 2012
U6  - https://doi.org/10.1111/j.1095-8339.2011.01185.x
SN  - 0024-4074
VL  - 168
IS  - 1
SP  - 64
EP  - 75
PB  - Wiley-Blackwell
CY  - Hoboken
ER  - 
TY  - JOUR
A1  - Kloss, Lena
A1  - Fischer, Markus
A1  - Durka, Walter
T1  - Land-use effects on genetic structure of a common grassland herb a matter of scale
JF  - Basic and applied ecology : Journal of the Gesellschaft für Ökologie
N2  - The most common management practices in European grasslands are grazing by livestock and mowing for silage and hay. Grazing and mowing differ in their potential effects on plant gene flow and resulting population genetic structure. After assessing its breeding system, we investigated the effect of land use on the population genetic structure in the common grassland plant Veronica chamaedrys using 63 study populations on meadows, mown pastures and pastures in three regions in Germany, the so-called Biodiversity Exploratories. We determined plant density and analysed the genetic diversity, differentiation and small-scale genetic structure using amplified fragment length polymorphism (AFLP) markers. The breeding system of V chamaedrys turned out as self-incompatible and outcrossing. Its genetic diversity did not differ among land-use types. This may be attributed to large population sizes and the strong dispersal ability of the species, which maintains genetically diverse populations not prone to genetic drift. Genetic differentiation among populations was low (overall F(ST) = 0.075) but significant among the three regions. Land use had only weak effects on population differentiation in only one region. However, land use affected small-scale genetic structure suggesting that gene flow within plots was more restricted on meadows than on mown and unmown pastures. Our study shows that land use influences genetic structure mainly at the small scale within populations, despite high gene flow.
KW  - Biodiversity exploratories
KW  - Mowing
KW  - Grazing
KW  - AFLP
KW  - Veronica
KW  - Breeding system
KW  - Pollination experiment
KW  - Pollen-ovule ratio
KW  - Isolation by distance
KW  - Spatial autocorrelation
Y1  - 2011
U6  - https://doi.org/10.1016/j.baae.2011.06.001
SN  - 1439-1791
VL  - 12
IS  - 5
SP  - 440
EP  - 448
PB  - Elsevier
CY  - Jena
ER  - 
TY  - JOUR
A1  - Gemeinholzer, B.
A1  - May, F.
A1  - Ristow, Michael
A1  - Batsch, C.
A1  - Lauterbach, D.
T1  - Strong genetic differentiation on a fragmentation gradient among populations of the heterocarpic annual Catananche lutea L. (Asteraceae)
JF  - Plant systematics and evolution
N2  - In landscapes which are predominately characterised by agriculture, natural ecosystems are often reduced to a mosaic of scattered patches of natural vegetation. Species with formerly connected distribution ranges now have restricted gene flow among populations. This has isolating effects upon population structure, because species are often confined by their limited dispersal capabilities. In this study, we test the effects of habitat fragmentation, precipitation, and isolation of populations on the genetic structure (AFLP) and fitness of the Asteraceae Catananche lutea. Our study area is an agro-dominated ecosystem in the desert-Mediterranean transition zone of the Southern Judea Lowlands in Israel. Our analysis revealed an intermediate level of intra-population genetic diversity across the study site with reduced genetic diversity on smaller scale. Although the size of the whole study area was relatively small (20 x 45 km), we found isolation by distance to be effective. We detected a high level of genetic differentiation among populations but genetic structure did not reflect spatial patterns. Population genetic diversity was correlated neither with position along the precipitation gradient nor with different seed types or other plant fitness variables in C. lutea.
KW  - AFLP
KW  - Heterocarpy
KW  - Population structure
KW  - Precipitation gradient
KW  - Asteraceae
Y1  - 2012
U6  - https://doi.org/10.1007/s00606-012-0661-1
SN  - 0378-2697
VL  - 298
IS  - 8
SP  - 1585
EP  - 1596
PB  - Springer
CY  - Wien
ER  - 
TY  - JOUR
A1  - Eckert, Silvia
A1  - Herden, Jasmin
A1  - Stift, Marc
A1  - Durka, Walter
A1  - Kleunen, Mark Van
A1  - Joshi, Jasmin Radha
T1  - Traces of Genetic but Not Epigenetic Adaptation in the Invasive Goldenrod Solidago canadensis Despite the Absence of Population Structure
JF  - Frontiers in Ecology and Evolution
N2  - Biological invasions may result from multiple introductions, which might compensate for reduced gene pools caused by bottleneck events, but could also dilute adaptive processes. A previous common-garden experiment showed heritable latitudinal clines in fitness-related traits in the invasive goldenrod Solidago canadensis in Central Europe. These latitudinal clines remained stable even in plants chemically treated with zebularine to reduce epigenetic variation. However, despite the heritability of traits investigated, genetic isolation-by-distance was non-significant. Utilizing the same specimens, we applied a molecular analysis of (epi)genetic differentiation with standard and methylation-sensitive (MSAP) AFLPs. We tested whether this variation was spatially structured among populations and whether zebularine had altered epigenetic variation. Additionally, we used genome scans to mine for putative outlier loci susceptible to selection processes in the invaded range. Despite the absence of isolation-by-distance, we found spatial genetic neighborhoods among populations and two AFLP clusters differentiating northern and southern Solidago populations. Genetic and epigenetic diversity were significantly correlated, but not linked to phenotypic variation. Hence, no spatial epigenetic patterns were detected along the latitudinal gradient sampled. Applying genome-scan approaches (BAYESCAN, BAYESCENV, RDA, and LFMM), we found 51 genetic and epigenetic loci putatively responding to selection. One of these genetic loci was significantly more frequent in populations at the northern range. Also, one epigenetic locus was more frequent in populations in the southern range, but this pattern was lost under zebularine treatment. Our results point to some genetic, but not epigenetic adaptation processes along a large-scale latitudinal gradient of S. canadensis in its invasive range.
KW  - AFLP
KW  - MSAP
KW  - cytosine methylation
KW  - spatial autocorrelation
KW  - genome scan
Y1  - 2022
U6  - https://doi.org/10.3389/fevo.2022.856453
SN  - 2296-701X
VL  - 10
SP  - 1
EP  - 17
PB  - Frontiers
CY  - Lausanne, Schweiz
ER  - 
TY  - JOUR
A1  - Eckert, Silvia
A1  - Herden, Jasmin
A1  - Stift, Marc
A1  - Durka, Walter
A1  - Kleunen, Mark Van
A1  - Joshi, Jasmin Radha
T1  - Traces of Genetic but Not Epigenetic Adaptation in the Invasive Goldenrod Solidago canadensis Despite the Absence of Population Structure
JF  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - Biological invasions may result from multiple introductions, which might compensate for reduced gene pools caused by bottleneck events, but could also dilute adaptive processes. A previous common-garden experiment showed heritable latitudinal clines in fitness-related traits in the invasive goldenrod Solidago canadensis in Central Europe. These latitudinal clines remained stable even in plants chemically treated with zebularine to reduce epigenetic variation. However, despite the heritability of traits investigated, genetic isolation-by-distance was non-significant. Utilizing the same specimens, we applied a molecular analysis of (epi)genetic differentiation with standard and methylation-sensitive (MSAP) AFLPs. We tested whether this variation was spatially structured among populations and whether zebularine had altered epigenetic variation. Additionally, we used genome scans to mine for putative outlier loci susceptible to selection processes in the invaded range. Despite the absence of isolation-by-distance, we found spatial genetic neighborhoods among populations and two AFLP clusters differentiating northern and southern Solidago populations. Genetic and epigenetic diversity were significantly correlated, but not linked to phenotypic variation. Hence, no spatial epigenetic patterns were detected along the latitudinal gradient sampled. Applying genome-scan approaches (BAYESCAN, BAYESCENV, RDA, and LFMM), we found 51 genetic and epigenetic loci putatively responding to selection. One of these genetic loci was significantly more frequent in populations at the northern range. Also, one epigenetic locus was more frequent in populations in the southern range, but this pattern was lost under zebularine treatment. Our results point to some genetic, but not epigenetic adaptation processes along a large-scale latitudinal gradient of S. canadensis in its invasive range.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1271 
KW  - AFLP
KW  - MSAP
KW  - cytosine methylation
KW  - spatial autocorrelation
KW  - genome scan
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-566758
SN  - 1866-8372
SP  - 1
EP  - 17
PB  - Universitätsverlag Potsdam
CY  - Potsdam
ER  - 
TY  - THES
A1  - Eckert, Silvia
T1  - Trait variation in changing environments: Assessing the role of DNA methylation in non-native plant species
T1  - Merkmalsvariation in sich verändernden Umgebungen: Bewertung der Rolle der DNA-Methylierung bei nicht einheimischen Pflanzenarten
N2  - The increasing introduction of non-native plant species may pose a threat to local biodiversity. However, the basis of successful plant invasion is not conclusively understood, especially since these plant species can adapt to the new range within a short period of time despite impoverished genetic diversity of the starting populations. In this context, DNA methylation is considered promising to explain successful adaptation mechanisms in the new habitat. DNA methylation is a heritable variation in gene expression without changing the underlying genetic information. Thus, DNA methylation is considered a so-called epigenetic mechanism, but has been studied in mainly clonally reproducing plant species or genetic model plants. An understanding of this epigenetic mechanism in the context of non-native, predominantly sexually reproducing plant species might help to expand knowledge in biodiversity research on the interaction between plants and their habitats and, based on this, may enable more precise measures in conservation biology.
For my studies, I combined chemical DNA demethylation of field-collected seed material from predominantly sexually reproducing species and rearing offsping under common climatic conditions to examine DNA methylation in an ecological-evolutionary context. The contrast of chemically treated (demethylated) plants, whose variation in DNA methylation was artificially reduced, and untreated control plants of the same species allowed me to study the impact of this mechanism on adaptive trait differentiation and local adaptation. With this experimental background, I conducted three studies examining the effect of DNA methylation in non-native species along a climatic gradient and also between climatically divergent regions.
The first study focused on adaptive trait differentiation in two invasive perennial goldenrod species, Solidago canadensis sensu latu and S. gigantea AITON, along a climate gradient of more than 1000 km in length in Central Europe. I found population differences in flowering timing, plant height, and biomass in the temporally longer-established S. canadensis, but only in the number of regrowing shoots for S. gigantea. While S. canadensis did not show any population structure, I was able to identify three genetic groups along this climatic gradient in S. gigantea. Surprisingly, demethylated plants of both species showed no change in the majority of traits studied. In the subsequent second study, I focused on the longer-established goldenrod species S. canadensis and used molecular analyses to infer spatial epigenetic and genetic population differences in the same specimens from the previous study. I found weak genetic but no epigenetic spatial variation between populations. Additionally, I was able to identify one genetic marker and one epigenetic marker putatively susceptible to selection. However, the results of this study reconfirmed that the epigenetic mechanism of DNA methylation appears to be hardly involved in adaptive processes within the new range in S. canadensis.
Finally, I conducted a third study in which I reciprocally transplanted short-lived plant species between two climatically divergent regions in Germany to investigate local adaptation at the plant family level. For this purpose, I used four plant families (Amaranthaceae, Asteraceae, Plantaginaceae, Solanaceae) and here I additionally compared between non-native and native plant species. Seeds were transplanted to regions with a distance of more than 600 kilometers and had either a temperate-oceanic or a temperate-continental climate. In this study, some species were found to be maladapted to their own local conditions, both in non-native and native plant species alike. In demethylated individuals of the plant species studied, DNA methylation had inconsistent but species-specific effects on survival and biomass production. The results of this study highlight that DNA methylation did not make a substantial contribution to local adaptation in the non-native as well as native species studied.
In summary, my work showed that DNA methylation plays a negligible role in both adaptive trait variation along climatic gradients and local adaptation in non-native plant species that either exhibit a high degree of genetic variation or rely mainly on sexual reproduction with low clonal propagation. I was able to show that the adaptive success of these non-native plant species can hardly be explained by DNA methylation, but could be a possible consequence of multiple introductions, dispersal corridors and meta-population dynamics. Similarly, my results illustrate that the use of plant species that do not predominantly reproduce clonally and are not model plants is essential to characterize the effect size of epigenetic mechanisms in an ecological-evolutionary context.
N2  - Die zunehmende Eintragung nicht-heimischer Pflanzenarten kann eine Gefahr für die lokale Artenvielfalt darstellen. Die Grundlagen einer erfolgreichen pflanzlichen Ausbreitung sind jedoch nicht abschließend geklärt, zumal sich diese Arten innerhalb kurzer Zeit an das neue Verbreitungsgebiet anpassen können trotz anfänglich reduzierter genetischer Vielfalt der Startpopulationen. In diesem Kontext gilt DNA-Methylierung als vielversprechend, um erfolgreiche Anpassungsmechanismen im neuen Lebensraum zu erklären. Bei der DNA-Methylierung handelt es sich um eine vererbbare Variation der Genaktivität, ohne dass die zugrundeliegende genetische Erbinformation verändert wird. Damit gehört DNA-Methylierung zu den sogenannten epigenetischen Mechanismen, wurde jedoch vorwiegend bei sich klonal vermehrenden Pflanzenarten oder genetischen Modellpflanzen untersucht. Ein Verständnis dieses epigenetischen Mechanismus im Zusammenhang mit nicht-einheimischen, sich vorwiegend sexuell reproduzierenden Pflanzenarten erweitert das Wissen in der Biodiversitätsforschung zur Interaktion zwischen Pflanzen und ihrem Lebensraum und kann, darauf aufbauend, präzisere Maßnahmen in der Naturschutzbiologie ermöglichen.
Für meine Studien kombinierte ich die chemische DNA-Demethylierung von im Freiland gesammeltem Samenmaterial sich vorwiegend sexuell fortpflanzender Arten und die Aufzucht unter gemeinsamen klimatischen Bedingungen, um DNA-Methylierung im ökologisch-evolutionären Kontext zu untersuchen. Der Kontrast von chemisch behandelten (demethylierten) Pflanzen, deren Methylierungsvariation nun künstlich verringert war, und unbehandelten Kontrollpflanzen derselben Art ermöglichte mir die Auswirkung dieses Mechanismus auf adaptive Merkmalsvariationen und lokale Anpassung zu studieren. Vor diesem experimentellen Hintergrund führte ich drei Studien durch, um die Auswirkung von DNA-Methylierung bei nicht-einheimischen Pflanzenarten entlang eines klimatischen Gradienten und zwischen zwei klimatisch unterschiedlichen Regionen zu untersuchen.
Die erste Studie konzentrierte sich auf adaptive Merkmalsveränderungen bei Nachkommen von zwei invasiven, mehrjährigen Goldrutenarten, Solidago canadensis sensu latu und S. gigantea AITON, entlang eines Klimagradienten von mehr als 1000 km Länge in Zentraleuropa. Ich fand graduelle Unterschiede im Blühzeitpunkt, in der Pflanzenhöhe und der Biomasse bei der zeitlich länger etablierten S. canadensis, bei S. gigantea jedoch nur in der Anzahl der nachwachsenden Triebe. Während S. canadensis keinerlei Populationsstruktur aufwies, konnte ich bei S. gigantea drei genetische Gruppen entlang dieses Klimagradienten identifizieren. Überraschenderweise zeigten demethylierte Pflanzen beider Arten keine Veränderung in der überwiegenden Anzahl der untersuchten Merkmale. In der darauffolgenden zweiten Studie konzentrierte ich mich auf die länger etablierte Goldrutenart S. canadensis und verwendete molekulare Analysen, um räumliche epigenetische und genetische Populationunterschiede aus den Exemplaren der vorhergehenden Studie abzuleiten. Ich fand schwache genetische aber keine epigenetische räumliche Variation zwischen den Populationen. Zusätzlich konnte ich einen genetischen und einen epigenetischen Marker identifizieren, welcher potentiell unter Selektion stehen könnte. Allerdings bestätigten die Ergebnisse dieser Studie erneut, dass DNA-Methylierung bei S. canadensis kaum in die Anpassung an das neue Verbreitungsgebiet involviert zu sein scheint.
Schließlich führte ich eine dritte Studie durch, in welcher ich Samen kurzlebiger Pflanzenarten reziprok zwischen zwei klimatisch unterschiedlichen Regionen in Deutschland transplantierte, um lokale Anpassung auf Ebene der Pflanzenfamilien zu untersuchen. Zu diesem Zweck nutze ich vier Pflanzenfamilien (Amaranthaceae, Asteraceae, Plantaginaceae, Solanaceae), wobei ich hier auch zwischen nicht-heimischen und heimischen Pflanzenarten verglich. Beide Regionen lagen mehr als 600 Kilometer voneinander entfernt und wiesen entweder ein gemäßigt-ozeanisches oder gemäßigt-kontinentales Klima auf. In dieser Studie zeigte sich für einige—sowohl nicht-einheimische als auch einhimische—Arten eine Fehlanpassung an die eigenen lokalen Bedingungen. In demethylierten Individuen der untersuchten Pflanzenarten wirkte sich die DNA-Methylierung widersprüchlich, aber artspezifisch auf das Überleben und die Biomasseproduktion aus. Die Ergebnisse dieser Studie unterstreichen, dass DNA-Methylierung einen vernachlässigbaren Beitrag zur lokalen Anpassung bei den untersuchten nicht-heimischen, aber auch einheimischen Arten leistete.
Zusammenfassend konnte ich mit dieser Arbeit festellen, dass DNA-Methylierung bei nicht-einheimischen Pflanzenarten eine untergeordnete Rolle sowohl bei der adaptiven Merkmalsvariation entlang von Klimagradienten als auch der lokalen Anpassung an klimatisch unterschiedliche Regionen spielt, wenn diese Pflanzenarten eine hohe genetische Vielfalt aufweisen und sich hauptsächlich sexuell vermehren. Ich konnte zeigen, dass der Anpassungserfolg dieser nicht-einheimischen Pflanzenarten kaum durch DNA-Methylierung erklärbar ist, sondern vielmehr eine mögliche Folge mehrfacher Eintragungen, von Ausbreitungskorridoren und Meta-Populationsdynamiken sein könnte. Die Ergebnisse dieser Studien verdeutlichen ebenso, dass die Verwendung von Pflanzenarten, die sich nicht überwiegend klonal vermehren und keine genetischen Modellpflanzen sind, unerlässlich ist, um die Effektstärke epigenetischer Mechanismen im ökologisch-evolutionären Kontext zu charakterisieren.
KW  - common-garden experiment
KW  - reciprocal transplant experiment
KW  - epigenetics
KW  - cytosine methylation
KW  - zebularine
KW  - adaptive differentiation
KW  - local adaptation
KW  - microsatellites
KW  - Solidago canadensis
KW  - Solidago gigantea
KW  - Amaranthus retroflexus
KW  - Chenopodium album
KW  - Erigeron canadensis
KW  - Erigeron annuus
KW  - Lactuca serriola
KW  - Senecio vulgaris
KW  - Sonchus oleraceus
KW  - Tripleurospermum inodorum
KW  - Veronica persica
KW  - Plantago major
KW  - Datura stramonium
KW  - Solanum nigrum
KW  - latitudinal clines
KW  - population structure
KW  - invasive
KW  - ruderal
KW  - non-native
KW  - Central Europe
KW  - Germany
KW  - AFLP
KW  - MSAP
KW  - spatial autocorrelation
KW  - genome scan
KW  - Gemeinschaftsgarten-Experiment
KW  - reziprokes Transplantationsexperiment
KW  - Epigenetik
KW  - Cytosin-Methylierung
KW  - Zebularin
KW  - adaptive Differenzierung
KW  - lokale Anpassung
KW  - Mikrosatelliten
KW  - Breitengrad
KW  - Ökokline
KW  - Populationsstruktur
KW  - invasiv
KW  - ruderal
KW  - nicht-einheimisch
KW  - Mitteleuropa
KW  - Deutschland
KW  - AFLP
KW  - MSAP
KW  - räumliche Autokorrelation
KW  - Genom-Scan
Y1  - 2022
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-568844
ER  -