The conservation and sustainable use of forest genetic resources (FGR) in the face of the threat posed by climate change has become a challenging task for scientists and foresters. Genetic variability and diversity of FGR and forest reproductive material (FRM) will play a key role in forest adaptation under future environmental conditions. The need for protection of FGR has been widely discussed on the pan-European and national scales. However, at the national level, in some countries, the conservation and use of rare and scattered tree species FGR is overlooked or given low priority. Our study focuses on the delineation of provenance regions, selection of seed stands and gene conservation units of wild service tree in southern Germany. A total of 106 natural populations of wild service tree were screened based on demographic and phenotypic criteria. In order to represent the distribution range of wild service tree in southern Germany, 34 populations were selected for genetic analysis with eight variable microsatellite markers in Bavaria (BY) and Baden-Württemberg (BW). Results of AMOVA (analysis of molecular variance) showed that genetic variation is mainly distributed within populations (96%), while only a small amount occurred among them (FST = 0.04). The Mantel test indicated isolation by distance, and Bayesian clustering indicated the highest probability of four genetic clusters of wild service tree in southern Germany. Finally, 12 stands out of 34 were proposed as seed stands based on high-quality phenotypes and high genetic diversity (effective no. of alleles Ne ≥ 5.5). Five populations were proposed as gene conservation units, and seven forest stands were included in the list as potential future seed stands. Overall, assessment of genetic diversity should be applied in future to evaluate the level of genetic diversity of all selected seed stands. Our study thus presents a concept for delineation of provenance regions, selection of seed stands and gene conservation units based on demographic–phenotypic parameters and genetic markers.
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We are deeply thankful to private forest owners for collaboration and permission to access their forest stands and to the state forest control officers Gert Günzelmann (BY), Erich Lang (BY), Anton Paulus (BY), Michael Luckas (BY), Matthias Wieners (BW) and Rainer Schmid (BW) for assistance with phenotypic stand evaluation and sampling. We thank Susanne Nowak for technical assistance in lab work.
The study was funded by the Bavarian Ministry of Food, Agriculture and Forestry, project—“Erarbeitung von Herkunftsempfehlungen und Verbesserung der Erntebasis für die seltene, klimatolerante Baumart Elsbeere (S. torminalis L.) in Bayern und in Baden-Württemberg” (Project No. ST 323). Data from the project “Bundesanstalt für Landwirtschaft und Ernährung (2013): Erfassung und Dokumentation genetischer Ressourcen seltener und gefährdeter Baumarten in Deutschland” were used for selection of stands to be visited by state forest control officers.
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Kavaliauskas, D., Šeho, M., Baier, R. et al. Genetic variability to assist in the delineation of provenance regions and selection of seed stands and gene conservation units of wild service tree (Sorbus torminalis (L.) Crantz) in southern Germany. Eur J Forest Res (2021). https://doi.org/10.1007/s10342-020-01352-x
- Provenance regions
- Forest genetic resources
- Genetic diversity
- Forest reproductive material