Tools
Tools
Bellis, J, Albrecht, MA, Maschinski, J, Dalrymple, SE, Keir, MJ, Chambers, T, Possley, J, Adkins, ED, Parsons, EW, Kunz, M, Radcliffe, C, Coffey, E, Kaye, TN, Peterson, CL, David, AS, Herron, SA, Menges, ES, Bell, T, Coppoletta, M, Elam, C , McEachern, K, Williamson, PS, Boensch, D, Bontrager, M, Breeden, C, Frade, N, Gordon, DR, Link, SO, Littlefield, T, Murray, S, O'Dell, R, Pavlovic, NB, Reemts, CM, Taylor, DD, Titus, JH, Titus, PJ, Stanley, TA and Heineman, KD (2025) The relative influence of geographic and environmental factors on rare plant translocation outcomes. Journal of Applied Ecology. ISSN 0021-8901
|
Text
The relative influence of geographic and environmental factors on rare plant translocation outcomes.pdf - Published Version Available under License Creative Commons Attribution Non-commercial No Derivatives. Download (2MB) | Preview |
Abstract
Conservation translocations are an established method for reducing the extinction risk of plant species through intentional movement within or outside the indigenous range. Unsuitable environmental conditions at translocation recipient sites and a lack of understanding of species–environment relationships are often identified as critical barriers to translocation success. However, previous syntheses have drawn these inferences from analyses of qualitative feedback rather than quantitative environmental data.
In this study, we use a data set of 235 translocations conducted in the US to understand the influences of geographic and environmental factors on three metrics of translocation success: population persistence, next-generation recruitment and next-generation maturity. We use random forest models to quantify the relative importance of geographic and environmental factors that characterize dissimilarity between source and recipient locations, the position of recipient sites relative to species' ranges and niche metrics derived from these ranges. We also compare the importance of these variables with more conventional predictors (e.g. founder population size).
Our results indicate that geographic and environmental variables can be as insightful as conventional variables for predicting plant translocation outcomes. The climate suitability of recipient sites, estimated using species distribution models, was the strongest relative predictor of whether a population persisted, with populations situated in more suitable climates displaying greater persistence. Next-generation recruitment and maturity were best predicted by niche metrics; species in more biotically limiting environments, including tropical regions and soils with high relative nutrient retention, as well as species with the broadest precipitation niches, were the least likely to attain these next-generation benchmarks. Synthesis and applications. Our study is one of the first to quantify the important role of spatial and climatic factors in rare plant translocation outcomes. We provide a novel geographic and environmental perspective on outcomes in plant translocations and demonstrate opportunities to improve translocation success not only by adhering to established best practice guidelines but also by integrating spatial modelling approaches into planning and management processes.
| Item Type: | Article |
|---|---|
| Uncontrolled Keywords: | 0501 Ecological Applications; 0502 Environmental Science and Management; 0602 Ecology; Ecology |
| Subjects: | G Geography. Anthropology. Recreation > GE Environmental Sciences |
| Divisions: | Biological and Environmental Sciences (from Sep 19) |
| Publisher: | Wiley |
| SWORD Depositor: | A Symplectic |
| Date Deposited: | 27 Jan 2025 09:38 |
| Last Modified: | 27 Jan 2025 09:45 |
| DOI or ID number: | 10.1111/1365-2664.14855 |
| URI: | https://researchonline.ljmu.ac.uk/id/eprint/25452 |
 |
View Item |