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Asplenium adiantum-nigrum (Aspleniaceae, Pteridophyta) breitet sich seit ca. 20 Jahren von seinem Arealrand im Rheinisch-Westfälischen Mittelgebirge ins Tiefland hinein aus. Die bislang in Nordrhein-Westfalen collin-montan verbreitete Farnart besaß dort bis zum Ende der 1980er Jahre eine stabile Verbreitungsgrenze mit Vorkommen an Felsstandorten des Ruhrtals (südliches Ruhrgebiet). Ausbreitungsgeschichte, Populationsentwicklung, Gesellschaftsanschluss sowie die neuen Wuchsorte werden dargestellt. Insgesamt konnten seit 1990 25 Neufunde, 16 davon im planaren Raum des Niederrheinischen Tieflandes und der Westfälischen Bucht, mit einer Gesamtpopulation von über 580 Individuen verzeichnet werden. Die Ursachen der Arealerweiterung werden anhand von vier Hypothesen und unter Berücksichtigung von Untersuchungsergebnissen aus West- und Nordwesteuropa diskutiert. Eine derzeit häufig diskutierte mögliche Ursache der Arealerweiterung ist die seit Jahren erkennbare Klimaerwärmung, bei der insbesondere die milderen Winter und wärmeren Sommer u.a. zu einer Veränderung der Luftfeuchtigkeit führen. Diese scheidet jedoch im Falle von Asplenium adiatum-nigrum zumindest als monokausale Erklärung aus. Die veränderten klimatischen Faktoren überlagern sich zeitgleich mit einer einhergehenden Luftverbesserung (insbesondere Verringerung der SO2-Immissionen) und höheren Stickstoffimmissionen, welche letztlich die Wuchsbedingungen des Farntaxons insgesamt positiv beeinflussen können. Ein belegbarer Zusammenhang zwischen Ausbreitung des Taxons und den veränderten Klima- sowie Umweltbedingungen ist derzeit allerdings nicht gegeben.
1. During the last century, the practice of fur farming in Europe led to the introduction of two mammal species from opposite ends of the world. With their subsequent unintentional escape from captivity or intentional releases, the process of slow expansion and establishment in Europe began. The raccoon Procyon lotor and the raccoon dog Nyctereutes procyonoides are included on the European Union’s list of invasive alien species.
2. We characterised the current climatic niches of the two species in their native ranges in North America and Asia, and compared them with their non-native-range niches in Europe, where we also projected climatic suitability. The aim was to locate suitable habitats beyond their current ranges and assess where a range expansion can be expected.
3. Niche comparison and the projection of climatic suitability in Europe were based on eight bioclimatic variables and presence records from the Global Biodiversity Information Facility database. For niche modelling, we applied the maximum entropy approach (Maxent) and used the native-range data for training.
4. Minimum temperature of the coldest month (bio06) was identified as the most important bioclimatic variable in the habitat suitability models for both species. Different tolerance levels regarding this variable might explain small differences between the species’ projected ranges, especially in the north and east of Europe. The high niche unfilling for both species in Europe suggests a potential for expansion beyond their present ranges.
5. With only little understanding of their ecological impacts in their new ranges, including the potential risk of Nyctereutes procyonoides as SARS-CoV-2 reservoir hosts, further research and management is required at various spatial scales in Europe.
Driven by globalization, urbanization and climate change, the distribution range of invasive vector species has expanded to previously colder ecoregions. To reduce health-threatening impacts on humans, insect vectors are extensively studied. Population genomics can reveal the genomic basis of adaptation and help to identify emerging trends of vector expansion. By applying whole genome analyses and genotype-environment associations to populations of the main dengue vector Aedes aegypti, sampled along an altitudinal gradient in Nepal (200–1300 m), we identify putatively adaptive traits and describe the species' genomic footprint of climate adaptation to colder ecoregions. We found two differentiated clusters with significantly different allele frequencies in genes associated to climate adaptation between the highland population (1300 m) and all other lowland populations (≤800 m). We revealed nonsynonymous mutations in 13 of the candidate genes associated to either altitude, precipitation or cold tolerance and identified an isolation-by-environment differentiation pattern. Other than the expected gradual differentiation along the altitudinal gradient, our results reveal a distinct genomic differentiation of the highland population. Local high-altitude adaptation could be one explanation of the population's phenotypic cold tolerance. Carrying alleles relevant for survival under colder climate increases the likelihood of this highland population to a worldwide expansion into other colder ecoregions.