Your search keyword '"Pellecchia, Marco"' showing total 4 results

1. Break zones in the distributions of alleles and species in alpine plants

Author

Thiel Egenter, C, Alvarez, N, Holderegger, R, Tribsch, A, Englisch, T, Wohlgemuth, T, Colli, Licia, Gaudeul, M, Gielly, L, Jogan, N, Linder, Hp, Negrini, Riccardo, Niklfeld, H, Pellecchia, Marco, Rioux, D, Schönswetter, P, Taberlet, P, Van Loo, M, Winkler, M, Gugerli, F., University of Zurich, and Gugerli, F

Subjects

AFLP, Alpine plants, Species distribution patterns, Allele distribution patterns, Settore BIO/03 - BOTANICA AMBIENTALE E APPLICATA, 580 Plants (Botany), Glacial survival, 10121 Department of Systematic and Evolutionary Botany, 1105 Ecology, Evolution, Behavior and Systematics, Genetic structure, European Alps, Floristic areas, Elevational range, 2303 Ecology

Published

2011

2. History or ecology? Substrate type as a major driver of patial genetic structure in Alpine plants

Author

Alvarez, N., Thiel Egenter, C., Tribsch, A., Holderegger, R., Manel, S., Schonswetter, P., Taberlet, P., Brodbeck, S., Gaudeul, M., Gielly, L., Kupfer, P., Mansion, G., Riccardo NEGRINI, Paun, O., Pellecchia, Marco, Rioux, D., Schupfer, F., Loo, M., Winkler, M., Gugerli, F., and Intrabiodiv, Consortium

Subjects

0106 biological sciences, Time Factors, Ecology (disciplines), Climate, Population genetics, Plant Development, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Soil, Species Specificity, genetic structure, Ecology, Evolution, Behavior and Systematics, Phylogeny, 030304 developmental biology, 0303 health sciences, Genetic diversity, Alpine plants, Geography, Settore AGR/17 - ZOOTECNICA GENERALE E MIGLIORAMENTO GENETICO, Ecology, Biodiversity, 15. Life on land, Plants, DNA Fingerprinting, Plant ecology, Habitat, 13. Climate action, Genetic structure, Common spatial pattern, Spatial variability

Abstract

Climatic history and ecology are considered the most important factors moulding the spatial pattern of genetic diversity. With the advent of molecular markers, species' historical fates have been widely explored. However, it has remained speculative what role ecological factors have played in shaping spatial genetic structures within species. With an unprecedented, dense large-scale sampling and genome-screening, we tested how ecological factors have influenced the spatial genetic structures in Alpine plants. Here, we show that species growing on similar substrate types, largely determined by the nature of bedrock, displayed highly congruent spatial genetic structures. As the heterogeneous and disjunctive distribution of bedrock types in the Alps, decisive for refugial survival during the ice ages, is temporally stable, concerted post-glacial migration routes emerged. Our multispecies study demonstrates the relevance of particular ecological factors in shaping genetic patterns, which should be considered when modelling species projective distributions under climate change scenarios.

Published

2009

3. Break zones in the distributions of alleles and species in alpine plants.

Author

Thiel-Egenter, Conny, Alvarez, Nadir, Holderegger, Rolf, Tribsch, Andreas, Englisch, Thorsten, Wohlgemuth, Thomas, Colli, Licia, Gaudeul, Myriam, Gielly, Ludovic, Jogan, Nejc, Linder, Hans Peter, Negrini, Riccardo, Niklfeld, Harald, Pellecchia, Marco, Rioux, Delphine, Schönswetter, Peter, Taberlet, Pierre, van Loo, Marcela, Winkler, Manuela, and Gugerli, Felix

Subjects

MOUNTAIN plants, SPECIES distribution, RESEARCH, MOUNTAINS

Abstract

We test for the congruence between allele-based range boundaries (break zones) in silicicolous alpine plants and species-based break zones in the silicicolous flora of the European Alps. We also ask whether such break zones coincide with areas of large elevational variation. The European Alps. On a regular grid laid across the entire Alps, we determined areas of allele- and species-based break zones using respective clustering algorithms, identifying discontinuities in cluster distributions (breaks), and quantifying integrated break densities (break zones). Discontinuities were identified based on the intra-specific genetic variation of 12 species and on the floristic distribution data from 239 species, respectively. Coincidence between the two types of break zones was tested using Spearman's correlation. Break zone densities were also regressed on topographical complexity to test for the effect of elevational variation. We found that two main break zones in the distribution of alleles and species were significantly correlated. Furthermore, we show that these break zones are in topographically complex regions, characterized by massive elevational ranges owing to high mountains and deep glacial valleys. We detected a third break zone in the distribution of species in the eastern Alps, which is not correlated with topographic complexity, and which is also not evident from allelic distribution patterns. Species with the potential for long-distance dispersal tended to show larger distribution ranges than short-distance dispersers. We suggest that the history of Pleistocene glaciations is the main driver of the congruence between allele-based and species-based distribution patterns, because occurrences of both species and alleles were subject to the same processes (such as extinction, migration and drift) that shaped the distributions of species and genetic lineages. Large elevational ranges have had a profound effect as a dispersal barrier for alleles during post-glacial immigration. Because plant species, unlike alleles, cannot spread via pollen but only via seed, and thus disperse less effectively, we conclude that species break zones are maintained over longer time spans and reflect more ancient patterns than allele break zones. [ABSTRACT FROM AUTHOR]

Published

2011

4. History or ecology? Substrate type as a major driver of patial genetic structure in Alpine plants.

Author

Alvarez, Nadir, Thiel-Egenter, Conny, Tribsch, Andreas, Holderegger, Rolf, Manel, Stéphanie, Schönswetter, Peter, Taberlet, Pierre, Brodbeck, Sabine, Gaudeul, Myriam, Gielly, Ludovic, Küpfer, Philippe, Mansion, Guilhem, Negrini, Riccardo, Paun, Ovidiu, Pellecchia, Marco, Rioux, Delphine, Schüpfer, Fanny, Van Loo, Marcela, Winkler, Manuela, and Gugerli, Felix

Subjects

MOUNTAIN plants, PLANT genetics, SHIELDS (Geology), GENETIC polymorphisms, PHYLOGEOGRAPHY, PLANT species diversity, CLIMATE change, ECOLOGICAL research

Abstract

Climatic history and ecology are considered the most important factors moulding the spatial pattern of genetic diversity. With the advent of molecular markers, species’ historical fates have been widely explored. However, it has remained speculative what role ecological factors have played in shaping spatial genetic structures within species. With an unprecedented, dense large-scale sampling and genome-screening, we tested how ecological factors have influenced the spatial genetic structures in Alpine plants. Here, we show that species growing on similar substrate types, largely determined by the nature of bedrock, displayed highly congruent spatial genetic structures. As the heterogeneous and disjunctive distribution of bedrock types in the Alps, decisive for refugial survival during the ice ages, is temporally stable, concerted post-glacial migration routes emerged. Our multispecies study demonstrates the relevance of particular ecological factors in shaping genetic patterns, which should be considered when modelling species projective distributions under climate change scenarios. [ABSTRACT FROM AUTHOR]

Published

2009