Data from: Using joint species distribution modelling to identify climatic and non-climatic drivers of Afrotropical ungulate distributions
Data files
Aug 10, 2024 version files 5.10 MB
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Presab_plus_climate_variables_PROTECTEDAREASONLY_Res10arcminutes_OpenHabitats.csv
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Presab_plus_climate_variables_PROTECTEDAREASONLY_Res10arcminutes_TropicalForests.csv
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Presab_plus_climate_variables_PROTECTEDAREASONLY_Res10arcminutes.csv
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README.md
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Trait_Data_AllUngulates.csv
Abstract
The relative importance of the different processes that determine the distribution of species and the assembly of communities is a key question in ecology. The distribution of any individual species is affected by a wide range of environmental variables as well as through interactions with other species; the resulting distributions determine the pool of species available to form local communities at fine spatial scales. A challenge in community ecology is that these interactions (e.g., competition, facilitation, etc.) often are not directly measurable. Here, we used Hierarchical Modelling of Species Communities (HMSC), a recently developed framework for joint species distribution modelling, to estimate the role of biotic effects alongside environmental factors using latent variables. We investigate the role of these factors determining species distributions in communities of Artiodactyla, Perissodactyla and Proboscidea in the Afrotropics, an area of peak species richness for hoofed mammals. We also calculate pairwise trait dissimilarity between these species, from a mixture of morphological and behavioural traits, and investigate the relationship between dissimilarity and estimated residual co-occurrence in the model. We find that while ungulate distributions appear to be predominantly determined (~70%) by climatic variables, such as precipitation, a substantial proportion of the variance in ungulate species distributions (~30%) can also be attributed to modelled latent variables that likely represent a combination of dispersal barriers and biotic factors. Although we find only a weak relationship between residual co-occurrence and trait dissimilarity, we suggest that our results may show evidence that biotic factors, likely influenced by historical barriers to species dispersal, are important in determining species communities over a continental area. The HMSC framework can be used to provide insight into factors affecting community assembly at broad scales, and to make more powerful predictions about future species distributions as we enter an era of increasing impacts from anthropogenic change.
README: Data from: Climatic Variables Alone do not Determine Ungulate Distributions in the Afrotropics
This repository contains all data used for the paper "Climatic Variables Alone do not Determine Ungulate Distributions in the Afrotropics".
Description of the Data and file structure
Presab_plus_climate_variables_PROTECTEDAREASONLY_Res10arcminutes.csv, _OpenHabitats.csv, _TropicalForests.csv
These three files contain presence/absence data for all ungulate species included in the analysis for all points in the Afrotropics at 10 arcminute resolution, with data derived from IUCN species range maps processed using the letsR package. Additionally, they contain environmental data for all points in the matrix for all 19 bioclimatic variables (from WorldClim) and land cover data (from the FAO Land and Water Division.)
Trait_Data_AllUngulates.csv
This file contains all trait data used in the calculation of Gower's Distance.
Sharing/Access Information
Other data (i.e. shp files for species ranges, protected areas boundaries) used in this analysis is not posted in order to comply with policies on reposting and/or redistribution of unmodified data, however, for more details on these, please feel free to contact the corresponding author (Alex Cranston)
All data was derived from the following sources:
- Shapefiles for species' distributions (except rhinos) taken from: IUCN. (2018). The IUCN Red List of Threatened Species (spatial data). Version 2018-2 . https://www.iucnredlist.org. Downloaded on 9 November 2021. Rhino distributions taken from Rookmaaker, K., & Antoine, P.-O. (2012). New maps representing the historical and recent distribution of the African species of rhinoceros: Diceros bicornis, Ceratotherium simum and Ceratotherium cottoni. Pachyderm, 52, 91–96. Retrieved from https://pachydermjournal.org/index.php/pachyderm/article/view/311.
- Global Land Cover map taken from: Latham, J., Cumani, R., Rosati, I., & Bloise, M. (2014). FAO Global Land Cover (GLC-SHARE) Beta-Release 1.0 Database. FAO Land and Water Division. https://data.apps.fao.org/map/catalog/sru/api/records/7f4f5ce4-9a3e-406f-bae6-efe63867329a
- Bioclimatic variables taken from: Fick, S. E., & Hijmans, R. J. (2017). WorldClim 2: new 1-km spatial resolution climate surfaces for global land areas. International Journal of Climatology, 37(12), 4302-4315. https://doi.org/https://doi.org/10.1002/joc.5086
- Shapefiles for African protected areas taken from: UNEP-WCMC, & IUCN. Protected Planet: The World Database on Protected Areas (WDPA) and World Database on Other Effective Area-based Conservation Measures (WD-OECM) [Online]. UNEP-WCMC and IUCN. Retrieved June 2022 from www.protectedplanet.net
- Shapefiles for African biomes taken from: Dinerstein, E., Olson, D., Joshi, A., Vynne, C., Burgess, N. D., Wikramanayake, E., Hahn, N., Paminteri, S., Hedao, P., Noss, R., Hansen, M., Locke, H., Ellis, E. C., Jones, B., Barber, C. V., Hayes, R., Kormos, C., Martin, V., Crist, E., Sechrest, W., Price, L., Baillie, J. E. M., Weeden, D., Suckling, K., Davis, C., Sizer, N., Moore, R., Thau, D., Birch, T., Potapov, P.,Turubanova, S., Tyukavina, A., de Souza, N., Pintea, L., Brito, J. C., Llewellyn, O. A., Miller, A. G., Patzelt, A., Ghazanfar, S. A., Timberlake, J., Klser, H., Shennan-Farpn, Y., Kindt, R., Lilles, J. B., van Breugel, P., Graudal, L., Voge, M., Al-Shammari, K. F., & Saleem, M. (2017). An ecoregion-based approach to protecting half the terrestrial realm. BioScience, 67(6), 534-545. https://doi.org/10.1093/biosci/bix014
- Trait data for body mass and body length taken from: Soria, C. D., Pacifici, M., Di Marco, M., Stephen, S. M., & Rondinini, C.. 2021. COMBINE: a coalesced mammal database of intrinsic and extrinsic traits. Ecology 102( 6):e03344. 10.1002/ecy.3344
- Trait data on diet mostly taken from: Gagnon, M., Chew, A. E., (2000) Dietary Preferences in Extant African Bovidae, Journal of Mammalogy, 81(2), 490511,https://doi.org/10.1644/1545-1542(2000)0810490:DPIEAB2.0.CO;2
- Additional trait data on diet estimated using Schlitter, D. A., Ferguson, A. W., & McDonough, M. M. (2014). Mammals of Africa (Vol. I-VI.). Journal of Mammalogy, 95(6), 1299-1303.999.
- Additional trait on migratory behaviour taken from Abraham, J. O., Hempson, G. P., Faith, J. T., & Staver, A. C.(2022). Seasonal strategies differ between tropical and extratropical herbivores. Journal of Animal Ecology, 91, 681–692. https://doi.org/10.1111/1365-2656.13651
Methods
Data were collected as described in the manuscript.