Substratum karstificability, dispersal and genetic structure in a strictly subterranean beetle

dc.contributor.author Rizzo, Valeria ca
dc.contributor.author Sánchez-Fernández, David ca
dc.contributor.author Alonso, Rocío ca
dc.contributor.author Pastor, Josep ca
dc.contributor.author Ribera, Ignacio ca
dc.contributor.other Consorci del Museu de Ciències Naturals de Barcelona ca
dc.coverage.spatial Barcelona ca
dc.coverage.spatial Barcelona en
dc.coverage.spatial Barcelona es
dc.date.accessioned 2020-12-16T12:25:11Z
dc.date.available 2020-12-16T12:25:11Z
dc.date.issued 2017-08-04
dc.description.abstract Aim The deep subterranean environment is an ideal system to test the effect of physical constraints on the ecology and evolution of species, as it is very homogeneous and with simple communities. We studied the effect of substratum karstificability in the dispersal of the strictly subterranean Troglocharinus ferreri (Reitter) (Coleoptera, Leiodidae) by comparing the genetic diversity and structure of populations in limestone (more soluble) and dolostone (less soluble) in the same karstic system. Location Troglocharinus ferreri is only known from c. 100 vertical shafts in an area of <500 km2 SW of Barcelona (Spain). Methods We sequenced mitochondrial and nuclear markers of a representative sample to identify main lineages within T. ferreri and estimate their temporal origin, and used mitochondrial data of 129 specimens from 41 caves to reconstruct their demographic history and estimate dispersal among caves. Results Troglocharinus ferreri diverged from its sister in the Early Pliocene, with an initial divergence of the sampled populations in the Early Pleistocene. The best demographic model was a constant population size with a fast population increase in the middle Pleistocene. The ancestral population was likely in limestone, with a probability of transition from limestone to dolostone triple to that from dolostone to limestone, suggesting a higher permeability of limestone to the transit of individuals. Populations in dolostone caves had lower gene flow between them and a stronger isolation by distance, although the low genetic variability for the studied markers and the lower abundance of dolostone caves decreased the statistical power of the analyses. Main conclusions Our results point to the physical characteristic of the substratum as a determinant of dispersal and gene flow, potentially conditioning the long‐term evolution of subterranean biodiversity. ca
dc.description.abstract Aim The deep subterranean environment is an ideal system to test the effect of physical constraints on the ecology and evolution of species, as it is very homogeneous and with simple communities. We studied the effect of substratum karstificability in the dispersal of the strictly subterranean Troglocharinus ferreri (Reitter) (Coleoptera, Leiodidae) by comparing the genetic diversity and structure of populations in limestone (more soluble) and dolostone (less soluble) in the same karstic system. Location Troglocharinus ferreri is only known from c. 100 vertical shafts in an area of <500 km2 SW of Barcelona (Spain). Methods We sequenced mitochondrial and nuclear markers of a representative sample to identify main lineages within T. ferreri and estimate their temporal origin, and used mitochondrial data of 129 specimens from 41 caves to reconstruct their demographic history and estimate dispersal among caves. Results Troglocharinus ferreri diverged from its sister in the Early Pliocene, with an initial divergence of the sampled populations in the Early Pleistocene. The best demographic model was a constant population size with a fast population increase in the middle Pleistocene. The ancestral population was likely in limestone, with a probability of transition from limestone to dolostone triple to that from dolostone to limestone, suggesting a higher permeability of limestone to the transit of individuals. Populations in dolostone caves had lower gene flow between them and a stronger isolation by distance, although the low genetic variability for the studied markers and the lower abundance of dolostone caves decreased the statistical power of the analyses. Main conclusions Our results point to the physical characteristic of the substratum as a determinant of dispersal and gene flow, potentially conditioning the long‐term evolution of subterranean biodiversity. en
dc.description.abstract Aim The deep subterranean environment is an ideal system to test the effect of physical constraints on the ecology and evolution of species, as it is very homogeneous and with simple communities. We studied the effect of substratum karstificability in the dispersal of the strictly subterranean Troglocharinus ferreri (Reitter) (Coleoptera, Leiodidae) by comparing the genetic diversity and structure of populations in limestone (more soluble) and dolostone (less soluble) in the same karstic system. Location Troglocharinus ferreri is only known from c. 100 vertical shafts in an area of <500 km2 SW of Barcelona (Spain). Methods We sequenced mitochondrial and nuclear markers of a representative sample to identify main lineages within T. ferreri and estimate their temporal origin, and used mitochondrial data of 129 specimens from 41 caves to reconstruct their demographic history and estimate dispersal among caves. Results Troglocharinus ferreri diverged from its sister in the Early Pliocene, with an initial divergence of the sampled populations in the Early Pleistocene. The best demographic model was a constant population size with a fast population increase in the middle Pleistocene. The ancestral population was likely in limestone, with a probability of transition from limestone to dolostone triple to that from dolostone to limestone, suggesting a higher permeability of limestone to the transit of individuals. Populations in dolostone caves had lower gene flow between them and a stronger isolation by distance, although the low genetic variability for the studied markers and the lower abundance of dolostone caves decreased the statistical power of the analyses. Main conclusions Our results point to the physical characteristic of the substratum as a determinant of dispersal and gene flow, potentially conditioning the long‐term evolution of subterranean biodiversity. es
dc.format.extent 28 p. ca
dc.identifier http://hdl.handle.net/2072/377626
dc.identifier.citation Journal of biogeography, Volume 44, Issue 11 (Nov. 2017), p. 2527-2538 ca
dc.identifier.entitat consorcis ca
dc.identifier.uri http://hdl.handle.net/11703/120393
dc.language eng ca
dc.provenance Recercat (Dipòsit de la Recerca de Catalunya) ca
dc.publisher Wiley ca
dc.subject Coleòpters ca
dc.subject Liòdids ca
dc.subject Roques sedimentàries ca
dc.subject Fauna cavernícola ca
dc.subject Genètica animal ca
dc.subject Beetles en
dc.subject Round fungus beetles en
dc.subject Sedimentary rocks en
dc.subject Cave animals en
dc.subject Animal genetics en
dc.subject Coleópteros es
dc.subject Leiódidos es
dc.subject Rocas sedimentarias es
dc.subject Fauna de cuevas es
dc.subject Genética animal es
dc.subject.category Ciència i tecnologia ca
dc.subject.forma articles ca
dc.title Substratum karstificability, dispersal and genetic structure in a strictly subterranean beetle ca
dc.type text ca
dc.type.driver info:eu-repo/semantics/article ca
dc.type.driver info:eu-repo/semantics/acceptedVersion ca
metadadalocal.dependencia 8008920

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