Differences in habitat quality explain nestedness in a land snail meta‐community
Identifieur interne : 007532 ( Main/Exploration ); précédent : 007531; suivant : 007533Differences in habitat quality explain nestedness in a land snail meta‐community
Auteurs : Kristoffer Hylander ; Christer Nilsson ; Bengt Gunnar Jonsson ; Tove GöthnerSource :
- Oikos [ 0030-1299 ] ; 2005-02.
Descripteurs français
- Wicri :
- topic : Forêt boréale, écologie, Habitat.
English descriptors
- KwdEn :
- Abundance data, Alnus incana, Alternative hypotheses, Assemblage, Assemblage increase, Basal, Basal area, Berglund, Boreal, Boreal forest, Bryophyte, Calcium content, Calicioid lichens, Cambridge univ, Community composition, Community structure, Conservation strategies, Correlated, Correlation coefficients, Deciduous, Deciduous basal area, Deciduous forests, Deciduous trees, Different mechanisms, Different predictions, Different species, Diversity hotspots, Ecology, Eigenvectors, Ellenberg indicator values, Environmental, Environmental variables, First axis, First ordination axis, Grey alder, Habitat, Habitat factors, Habitat heterogeneity, Habitat nestedness, Habitat properties, Habitat quality, Habitat quality hypothesis, Habitat type, Habitat variables, Habitats hypothesis, Hylander, Indicator values, Jonsson, Land molluscs, Land snail communities, Land snail species, Land snails, Large islands, Larger plot, Lateral slopes, Litter, Litter dwelling land snails, Litter dwelling snails, Litter samples, Litter volume, Many sites, Many species, Matrix, Mature forest, Mesic ground, Nature reserves, Nesovitrea petronella, Nestedness, Nestedness analysis, Nilsson, Null model, Oecologia, Oikos, Ordination, Ordination axis, Ordination techniques, Perfect nestedness, Populus tremula, Positive eigenvectors, Random simulations, Rank correlation, Rare species, Richness, Riparian, Sampling artefacts, Second subplot, Significant nestedness, Site index, Small streams, Snail, Snail species, Southern sweden, Species, Species composition, Species decreases, Species numbers, Species richness, Species subsets, Subset, Subset patterns, Terrestrial gastropods, Total abundance, Transect plot, Ultimate test, Vascular plants, Wareborn, Young specimens.
- Teeft :
- Abundance data, Alnus incana, Alternative hypotheses, Assemblage, Assemblage increase, Basal, Basal area, Berglund, Boreal, Boreal forest, Bryophyte, Calcium content, Calicioid lichens, Cambridge univ, Community composition, Community structure, Conservation strategies, Correlated, Correlation coefficients, Deciduous, Deciduous basal area, Deciduous forests, Deciduous trees, Different mechanisms, Different predictions, Different species, Diversity hotspots, Ecology, Eigenvectors, Ellenberg indicator values, Environmental, Environmental variables, First axis, First ordination axis, Grey alder, Habitat, Habitat factors, Habitat heterogeneity, Habitat nestedness, Habitat properties, Habitat quality, Habitat quality hypothesis, Habitat type, Habitat variables, Habitats hypothesis, Hylander, Indicator values, Jonsson, Land molluscs, Land snail communities, Land snail species, Land snails, Large islands, Larger plot, Lateral slopes, Litter, Litter dwelling land snails, Litter dwelling snails, Litter samples, Litter volume, Many sites, Many species, Matrix, Mature forest, Mesic ground, Nature reserves, Nesovitrea petronella, Nestedness, Nestedness analysis, Nilsson, Null model, Oecologia, Oikos, Ordination, Ordination axis, Ordination techniques, Perfect nestedness, Populus tremula, Positive eigenvectors, Random simulations, Rank correlation, Rare species, Richness, Riparian, Sampling artefacts, Second subplot, Significant nestedness, Site index, Small streams, Snail, Snail species, Southern sweden, Species, Species composition, Species decreases, Species numbers, Species richness, Species subsets, Subset, Subset patterns, Terrestrial gastropods, Total abundance, Transect plot, Ultimate test, Vascular plants, Wareborn, Young specimens.
Abstract
We set up two alternative hypotheses on how environmental variables could foster nestedness; one of “nested habitats” and another of “nested habitat quality”. The former hypothesis refers to situations where the nestedness of species depends on a nestedness of discrete habitats. The latter considers situations where all species in an assemblage increase in abundance along the same environmental gradient, but differ in specialisation or tolerance. We tested whether litter‐dwelling land snails (terrestrial gastropods) in boreal riparian forest exhibited a nested community structure, whether such a pattern was related to differences in environmental variables among sites, and which of the two hypotheses that best could account for the found pattern. We sampled litter from 100 m2 plots in 29 mature riparian forest sites along small streams in the boreal zone of Sweden. The number of snail species varied between 3 and 14 per site. Ranking the species‐by‐site matrix by PCA scores of the first ordination axis revealed a similarly significant nested pattern as when the matrix was sorted by number of species, showing that the species composition in this meta‐community can be properly described as nested. Several environmental variables, most notably pH index, were correlated with the first PCA axis. All but two species had positive eigenvectors in the PCA ordination and the abundance increased considerably along the gradient for most of the species implying that the hypothesis of “nested habitats” was rejected in favour of the “nested habitat quality” hypothesis. Analyses of nestedness have seldom been performed on equal sized plots, and our study shows the importance of understanding that variation in environmental variables among sites can result in nested communities. The conservation implications are different depending on which of our two hypotheses is supported; a conservation focus on species “hotspots” is more appropriate if the communities are nested because of “nested habitat quality”.
Url:
DOI: 10.1111/j.0030-1299.2005.13400.x
Affiliations:
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Publishers</publisher><pubPlace>Copenhagen</pubPlace><date type="published" when="2005-02">2005-02</date></imprint><idno type="ISSN">0030-1299</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0030-1299</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Abundance data</term><term>Alnus incana</term><term>Alternative hypotheses</term><term>Assemblage</term><term>Assemblage increase</term><term>Basal</term><term>Basal area</term><term>Berglund</term><term>Boreal</term><term>Boreal forest</term><term>Bryophyte</term><term>Calcium content</term><term>Calicioid lichens</term><term>Cambridge univ</term><term>Community composition</term><term>Community structure</term><term>Conservation strategies</term><term>Correlated</term><term>Correlation coefficients</term><term>Deciduous</term><term>Deciduous basal area</term><term>Deciduous forests</term><term>Deciduous trees</term><term>Different mechanisms</term><term>Different predictions</term><term>Different species</term><term>Diversity hotspots</term><term>Ecology</term><term>Eigenvectors</term><term>Ellenberg indicator values</term><term>Environmental</term><term>Environmental variables</term><term>First axis</term><term>First ordination axis</term><term>Grey alder</term><term>Habitat</term><term>Habitat factors</term><term>Habitat heterogeneity</term><term>Habitat nestedness</term><term>Habitat properties</term><term>Habitat quality</term><term>Habitat quality hypothesis</term><term>Habitat type</term><term>Habitat variables</term><term>Habitats hypothesis</term><term>Hylander</term><term>Indicator values</term><term>Jonsson</term><term>Land molluscs</term><term>Land snail communities</term><term>Land snail species</term><term>Land snails</term><term>Large islands</term><term>Larger plot</term><term>Lateral slopes</term><term>Litter</term><term>Litter dwelling land snails</term><term>Litter dwelling snails</term><term>Litter samples</term><term>Litter volume</term><term>Many sites</term><term>Many species</term><term>Matrix</term><term>Mature forest</term><term>Mesic ground</term><term>Nature reserves</term><term>Nesovitrea petronella</term><term>Nestedness</term><term>Nestedness analysis</term><term>Nilsson</term><term>Null model</term><term>Oecologia</term><term>Oikos</term><term>Ordination</term><term>Ordination axis</term><term>Ordination techniques</term><term>Perfect nestedness</term><term>Populus tremula</term><term>Positive eigenvectors</term><term>Random simulations</term><term>Rank correlation</term><term>Rare species</term><term>Richness</term><term>Riparian</term><term>Sampling artefacts</term><term>Second subplot</term><term>Significant nestedness</term><term>Site index</term><term>Small streams</term><term>Snail</term><term>Snail species</term><term>Southern sweden</term><term>Species</term><term>Species composition</term><term>Species decreases</term><term>Species numbers</term><term>Species richness</term><term>Species subsets</term><term>Subset</term><term>Subset patterns</term><term>Terrestrial gastropods</term><term>Total abundance</term><term>Transect plot</term><term>Ultimate test</term><term>Vascular plants</term><term>Wareborn</term><term>Young specimens</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Abundance data</term><term>Alnus incana</term><term>Alternative hypotheses</term><term>Assemblage</term><term>Assemblage increase</term><term>Basal</term><term>Basal area</term><term>Berglund</term><term>Boreal</term><term>Boreal forest</term><term>Bryophyte</term><term>Calcium content</term><term>Calicioid lichens</term><term>Cambridge univ</term><term>Community composition</term><term>Community structure</term><term>Conservation strategies</term><term>Correlated</term><term>Correlation coefficients</term><term>Deciduous</term><term>Deciduous basal area</term><term>Deciduous forests</term><term>Deciduous trees</term><term>Different mechanisms</term><term>Different predictions</term><term>Different species</term><term>Diversity hotspots</term><term>Ecology</term><term>Eigenvectors</term><term>Ellenberg indicator values</term><term>Environmental</term><term>Environmental variables</term><term>First axis</term><term>First ordination axis</term><term>Grey alder</term><term>Habitat</term><term>Habitat factors</term><term>Habitat heterogeneity</term><term>Habitat nestedness</term><term>Habitat properties</term><term>Habitat quality</term><term>Habitat quality hypothesis</term><term>Habitat type</term><term>Habitat variables</term><term>Habitats hypothesis</term><term>Hylander</term><term>Indicator values</term><term>Jonsson</term><term>Land molluscs</term><term>Land snail communities</term><term>Land snail species</term><term>Land snails</term><term>Large islands</term><term>Larger plot</term><term>Lateral slopes</term><term>Litter</term><term>Litter dwelling land snails</term><term>Litter dwelling snails</term><term>Litter samples</term><term>Litter volume</term><term>Many sites</term><term>Many species</term><term>Matrix</term><term>Mature forest</term><term>Mesic ground</term><term>Nature reserves</term><term>Nesovitrea petronella</term><term>Nestedness</term><term>Nestedness analysis</term><term>Nilsson</term><term>Null model</term><term>Oecologia</term><term>Oikos</term><term>Ordination</term><term>Ordination axis</term><term>Ordination techniques</term><term>Perfect nestedness</term><term>Populus tremula</term><term>Positive eigenvectors</term><term>Random simulations</term><term>Rank correlation</term><term>Rare species</term><term>Richness</term><term>Riparian</term><term>Sampling artefacts</term><term>Second subplot</term><term>Significant nestedness</term><term>Site index</term><term>Small streams</term><term>Snail</term><term>Snail species</term><term>Southern sweden</term><term>Species</term><term>Species composition</term><term>Species decreases</term><term>Species numbers</term><term>Species richness</term><term>Species subsets</term><term>Subset</term><term>Subset patterns</term><term>Terrestrial gastropods</term><term>Total abundance</term><term>Transect plot</term><term>Ultimate test</term><term>Vascular plants</term><term>Wareborn</term><term>Young specimens</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Forêt boréale</term><term>écologie</term><term>Habitat</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">We set up two alternative hypotheses on how environmental variables could foster nestedness; one of “nested habitats” and another of “nested habitat quality”. The former hypothesis refers to situations where the nestedness of species depends on a nestedness of discrete habitats. The latter considers situations where all species in an assemblage increase in abundance along the same environmental gradient, but differ in specialisation or tolerance. We tested whether litter‐dwelling land snails (terrestrial gastropods) in boreal riparian forest exhibited a nested community structure, whether such a pattern was related to differences in environmental variables among sites, and which of the two hypotheses that best could account for the found pattern. We sampled litter from 100 m2 plots in 29 mature riparian forest sites along small streams in the boreal zone of Sweden. The number of snail species varied between 3 and 14 per site. Ranking the species‐by‐site matrix by PCA scores of the first ordination axis revealed a similarly significant nested pattern as when the matrix was sorted by number of species, showing that the species composition in this meta‐community can be properly described as nested. Several environmental variables, most notably pH index, were correlated with the first PCA axis. All but two species had positive eigenvectors in the PCA ordination and the abundance increased considerably along the gradient for most of the species implying that the hypothesis of “nested habitats” was rejected in favour of the “nested habitat quality” hypothesis. Analyses of nestedness have seldom been performed on equal sized plots, and our study shows the importance of understanding that variation in environmental variables among sites can result in nested communities. The conservation implications are different depending on which of our two hypotheses is supported; a conservation focus on species “hotspots” is more appropriate if the communities are nested because of “nested habitat quality”.</div></front></TEI><affiliations><list></list><tree><noCountry><name sortKey="Gothner, Tove" sort="Gothner, Tove" uniqKey="Gothner T" first="Tove" last="Göthner">Tove Göthner</name><name sortKey="Gunnar Jonsson, Bengt" sort="Gunnar Jonsson, Bengt" uniqKey="Gunnar Jonsson B" first="Bengt" last="Gunnar Jonsson">Bengt Gunnar Jonsson</name><name sortKey="Hylander, Kristoffer" sort="Hylander, Kristoffer" uniqKey="Hylander K" first="Kristoffer" last="Hylander">Kristoffer Hylander</name><name sortKey="Nilsson, Christer" sort="Nilsson, Christer" uniqKey="Nilsson C" first="Christer" last="Nilsson">Christer Nilsson</name></noCountry></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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