Range‐weighted metrics of species and phylogenetic turnover can better resolve biogeographic transition zones

Laffan, Shawn W.; Rosauer, Dan F.; Virgilio, Giovanni Di; Miller, Joe; González‐Orozco, Carlos E.; Knerr, Nunzio; Thornhill, Andrew H.; Mishler, Brent D.

doi:10.1111/2041-210x.12513

Cited by 65 publications

(80 citation statements)

References 35 publications

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“…In most cases neo-endemism involves rapid phenotypic (e.g. (A) WE is the fraction of the range of each taxon occurring across the sampling area (Crisp et al 2001, Laffan et al 2016. Several species of Gallirallus have independently evolved flightless insular endemics.…”

Section: Discussionmentioning

confidence: 99%

“…SR is the absolute number of species and WE is the sum of the proportions of species ranges represented in each equalarea square grid cells (Crisp et al 2001, Laffan and Crisp 2003, Lee and Mishler 2014, Laffan et al 2016. Species richness (SR) and weighted endemism (WE) were used to evaluate the distribution of taxonomic diversity (richness).…”

Section: Patterns In the Spatial Distribution Of Diversity And Endemismmentioning

confidence: 99%

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Contrasting patterns of diversification in a bird family (Aves: Gruiformes: Rallidae) are revealed by analysis of geospatial distribution of species and phylogenetic diversity

2018

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Geospatial patterns in the distribution of regional biodiversity reflect the composite processes that underpin evolution: speciation, dispersal and extinction. The spatial distribution and phylogeny of a globally widespread and species rich bird family (Rallidae) were used to help assess the role of large-scale biogeographical processes in diversity and diversification. Here, we examine how different geostatistical diversity metrics enhance our understanding of species distribution by linking occurrence records of rail species to corresponding species level phylogeny. Tropical regions and temperate zones contained a large proportion of rail species richness and phylogenetic diversity whilst small islands in Australian, Oceanian and Oriental regions held the highest weighted and phylogenetic endemism. Our results suggest that habitat connectivity and dispersal were important ecological features in rail evolution and distribution. Spatial isolation was a significant driver of diversification where islands in Oceania were centres of neo-endemism with recent multiple and independent speciation events and could be considered as nurseries of biodiversity. Palaeo-endemism was mostly associated with older stable regions, so despite extensive long distance range shifting these areas retain their own ancient and distinct character. Madagascar was the major area of palaeo-endemism associated with the oldest rail lineages and could be considered a museum of rail diversity. This implies a mixture of processes determine the current distribution and diversity of rail clades with some areas dominated by recent 'in situ' speciation while others harbour old diversity with ecological traits that have stood the test of time.

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Section: Discussionmentioning

confidence: 99%

Section: Patterns In the Spatial Distribution Of Diversity And Endemismmentioning

confidence: 99%

Contrasting patterns of diversification in a bird family (Aves: Gruiformes: Rallidae) are revealed by analysis of geospatial distribution of species and phylogenetic diversity

2018

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“…The methods used in this study are time consuming and analog, but more or less reliable, providing hypotheses for cross-validation using more advanced statistical tools. Recent developments in computational spatial analyses for identifying zones of biotic turnover [3,81] will be important in further quantifying and refining the extent of barriers recognized here and elsewhere.…”

Section: Discussionmentioning

confidence: 99%

Congruent biogeographical disjunctions at a continent-wide scale: Quantifying and clarifying the role of biogeographic barriers in the Australian tropics

et al. 2017

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AimTo test whether novel and previously hypothesized biogeogaphic barriers in the Australian Tropics represent significant disjunction points or hard barriers, or both, to the distribution of plants.LocationAustralian tropics: Australian Monsoon Tropics and Australian Wet Tropics.MethodsThe presence or absence of 6,861 plant species was scored across 13 putative biogeographic barriers in the Australian Tropics, including two that have not previously been recognised. Randomizations of these data were used to test whether more species showed disjunctions (gaps in distribution) or likely barriers (range limits) at these points than expected by chance.ResultsTwo novel disjunctions in the Australian Tropics flora are identified in addition to eleven putative barriers previously recognized for animals. Of these, eleven disjunction points (all within the Australian Monsoon Tropics) were found to correspond to range-ending barriers to a significant number of species, while neither of the two disjunctions found within the Australian Wet Tropics limited a significant number of species’ ranges.Main conclusionsBiogeographic barriers present significant distributional limits to native plant species in the Australian Monsoon Tropics but not in the Australian Wet Tropics.

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“…From these grid cells several measures of biodiversity can be calculated, such as richness (the total number of taxa within the cell), weighted endemism (WE) (the summed inverse range of all taxa, generally species, in a cell) and corrected weighted endemism (CWE) (the averaged inverse range of all taxa in a cell (Laffan et al 2016)). From these grid cells several measures of biodiversity can be calculated, such as richness (the total number of taxa within the cell), weighted endemism (WE) (the summed inverse range of all taxa, generally species, in a cell) and corrected weighted endemism (CWE) (the averaged inverse range of all taxa in a cell (Laffan et al 2016)).…”

Section: Introductionmentioning

confidence: 99%

“…In the WPGMA (weighted pair-group method using arithmetic averages) clustering algorithm used in the Biodiverse software package (Laffan et al 2010), a distance or turnover metric compares the composition of taxa between cells to create a similarity tree or dendrogram, with cells that are grouped within the same branch being more similar. Three commonly used similarity metrics include the Jaccard, Sorenson and Beta Simpson, and each have their advantages (Laffan et al 2016). Three commonly used similarity metrics include the Jaccard, Sorenson and Beta Simpson, and each have their advantages (Laffan et al 2016).…”

Section: Introductionmentioning

confidence: 99%

A comparison of network and clustering methods to detect biogeographical regions

2017

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Bioregions are an important concept in biogeography, and are key to our understanding of biodiversity patterns across the world. The use of networks in biogeography to produce bioregions is a relatively novel approach that has been proposed to improve upon current methods. However, it remains unclear if they may be used in place of current methods and/or offer additional biogeographic insights. We compared two network methods to detect bioregions (modularity and map equation) with the conventional distance-based clustering method. We also explored the relationship between network and biodiversity metrics. For the analysis we used two datasets of iconic Australian plant groups at a continental scale, Acacia and eucalypts, as example groups. The modularity method detected fewer large bioregions produced the most succinct bioregionalisation for both plant groups corresponding to Australian biomes, while map equation detected many small bioregions including interzones at a natural scale of one. The clustering method was less sensitive than network methods in detecting bioregions. The network metric called participation coefficient from both network partition methods identified interzones or transition zones between bioregions. Furthermore, another network metric (betweenness) was highly correlated to richness and endemism. We conclude that the application of networks to biogeography offers a number of advantages and provides novel insights. More specifically, our study showed that these network partition methods were more efficient than the clustering method for bioregionalisation of continental-scale data in: 1) the identification of bioregions and 2) the quantification of biogeographic transition zones using the participation coefficient metric. The use of network methods and especially the participation coefficient metric adds to bioregionalisation by identifying transition zones which could be useful for conservation purposes and identifying biodiversity hotspots.

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Range‐weighted metrics of species and phylogenetic turnover can better resolve biogeographic transition zones

Cited by 65 publications

References 35 publications

Contrasting patterns of diversification in a bird family (Aves: Gruiformes: Rallidae) are revealed by analysis of geospatial distribution of species and phylogenetic diversity

Contrasting patterns of diversification in a bird family (Aves: Gruiformes: Rallidae) are revealed by analysis of geospatial distribution of species and phylogenetic diversity

Congruent biogeographical disjunctions at a continent-wide scale: Quantifying and clarifying the role of biogeographic barriers in the Australian tropics

A comparison of network and clustering methods to detect biogeographical regions

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