Diversity gradients of terrestrial vertebrates – substantial variations about a common theme

Raz, T.; Allison, A.; Avila, L. J.; Bauer, A. M.; Böhm, M.; Caetano, G. H. de O.; Colli, G.; Doan, T. M.; Doughty, P.; Grismer, L.; Itescu, Y.; Kraus, F.; Martins, M.; Morando, M.; Murali, G.; Nagy, Z. T.; Nogueira, C. de C.; Novosolov, M.; Oliver, P. M.; Passos, P.; Pincheira‐Donoso, D.; Sindaco, R.; Slavenko, A.; Torres‐Carvajal, O.; Uetz, P.; Wagner, P.; Zimin, A.; Roll, U.; Meiri, S.

doi:10.1111/jzo.13130

Cited by 3 publications

(3 citation statements)

References 127 publications

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“…At least for the DivRate based on the fair proportion approach and BAMM, the coefficient of variation for the 75% of the data remained below the 10% threshold, except for sharks. On the other hand, the presence-absence matrices successfully recovered the well-known latitudinal patterns of diversity for the five vertebrate groups (Jenkins et al, 2013; Raz et al, 2023), exhibiting a general trend of higher species richness in tropical regions (Fig. 3), although showing specific variations in the main areas with the highest species richnes.…”

Section: Resultsmentioning

confidence: 84%

A dataset containing speciation rates, uncertainty, and presence-absence matrices for more than 34,000 vertebrate species

Vásquez-Restrepo

2024

Preprint

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Motivation:Today, the large amount and availability of phylogenetic data have allowed the exploration of different types of patterns at various evolutionary and spatial scales. However, the calculation of some metrics used for this purpose can be computationally demanding and complex, such as those related to diversification rates. Therefore, the existence of a database that provides such information can streamline the process. It also makes science fairer and more accessible for those without access to great computational power or advanced programming skills.Main types of variables contained:Continuous and binary data depicting the speciation rates and presence-absence matrices, respectively, for more than 34,000 vertebrate species.Spatial location and grain:Worldwide at a specific level.Time period and grain:Present, but based on phylogenetic hypotheses for groups with between 300-100 Myr of evolutionary history.Major taxa and level of measurement:Vertebrates, including the Lissamphibia subclass (amphibians), the Squamata suborder (reptiles), and the classes Aves (birds), Mammalia (mammals), and Chondrichthyes (sharks), all of them at the species level.Software format:Various, including Excel files (.xlsx), nexus files (.nex), tree files (.tre), text files (.txt), raster files (.tiff), and RData files (.RData).

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Section: Resultsmentioning

confidence: 84%

A dataset containing speciation rates, uncertainty, and presence-absence matrices for more than 34,000 vertebrate species

Vásquez-Restrepo

2024

Preprint

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“…We used those primary climate variables to calculate 4 bioclimatic variables: mean annual temperature (bio01), temperature seasonality (bio04), as temperature influences reptiles and amphibians reproductive ecology and metabolism (Shine, 2005; Taylor et al, 2021), mean annual precipitation (bio12) and precipitation seasonality (bio15). Those variables explain most of the climatic variation at global scale (Buckley & Jetz, 2008; Raz et al, 2024) and other factors such as summer and winter temperatures exhibit significant correlations with linear combinations of these 4 variables. We retrieved species’ distribution from the IUCN Red List spatial data repository, which provided distribution information for 5,657 amphibians, 9,203 squamates and 121 testudines.…”

Section: Methodsmentioning

confidence: 99%

Generation length of the world’s amphibians and reptiles

Mancini,

Santini,

Cazalis

et al. 2024

Preprint

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Variation in life histories influences demographic processes from adaptive changes to population declines leading to extinction. Among life history traits, generation length offers a critical feature to forecast species demographic trajectories such as population declines (widely used by the IUCN Red List of Threatened Species) and adaptability to environmental change over time. Therefore, estimates of generation length are crucial to monitor demographic stability or future change in highly threatened organisms, particularly ectothermic tetrapods (amphibians and reptiles), which rank among the most threatened groups, but for which uncertainty in future impacts remains high. Despite its importance, generation length for amphibians and reptiles is largely missing. Here, we aimed to fill-in this gap by modeling generation lengths for amphibians, squamates and testudines as a function of species size, climate, life history, and phylogeny using generalized additive models and phylogenetic generalized least squares. We obtained estimates of generation lengths for 4,543 (52%) amphibians, 8,464 (72%) squamates and 118 (32%) testudines. Our models performed well for most families, for example Bufonidae in amphibians, Lacertidae and Colubridae in squamates and Geoemydidae in testudines, while we found high uncertainty around the prediction of a few families, notably Chamaeleonidae. Species body size and mean temperature were the main predictors of generation length in all groups. Although our estimates are not meant to substitute robust and validated measurements from field studies or natural history museums, they can help reduce existing biases in conservation assessments until field data will be comprehensively available.

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“…With such great variation in basic biological attributes, it is unsurprising that squamates are ubiquitous in all terrestrial biomes, except the coldest ones, across all continents and tiny, often very remote, islands. Indeed, squamates are relatively more successful than other vertebrates in colonising and persisting in warm deserts and islands (Raz et al, 2024;Roll et al, 2017).…”

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confidence: 99%

SquamBase—A database of squamate (Reptilia: Squamata) traits

Meiri

2024

Global Ecol Biogeogr

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MotivationI present a database that contains information on multiple key traits for all 11,744 recognised species of squamates worldwide. The database encompasses key traits and a reasonably comprehensive picture of available public knowledge. I present comprehensive description of the sources and rationale leading to the assignment of each particular trait state for each species. I hope the dataset can serve the scientific community, promote research and understanding of the group, comparisons with other taxa, and assessment of conservation needs. Furthermore, gaps in our knowledge of squamate traits become readily apparent and will hopefully lead to further study and even better knowledge.Main types of variables containedMorphological, ecological, life history, geographical and conservation‐related traits.Spatial locationGlobal.Time periodLate Holocene to recent.Major taxa and level of measurementSquamata, species.Software formatxlsx.

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Diversity gradients of terrestrial vertebrates – substantial variations about a common theme

Cited by 3 publications

References 127 publications

A dataset containing speciation rates, uncertainty, and presence-absence matrices for more than 34,000 vertebrate species

A dataset containing speciation rates, uncertainty, and presence-absence matrices for more than 34,000 vertebrate species

Generation length of the world’s amphibians and reptiles

SquamBase—A database of squamate (Reptilia: Squamata) traits

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