Abstract
Species distribution models can be used to direct early detection of invasive species, if they include proxies for invasion pathways. Due to the dynamic nature of invasion, these models violate assumptions of stationarity across space and time. To compensate for issues of stationarity, we iteratively update regionalized species distribution models annually for European gypsy moth (Lymantria dispar dispar) to target early detection surveys for the USDA APHIS gypsy moth program. We defined regions based on the distances from the invasion spread front where shifts in variable importance occurred and included models for the non-quarantine portion of the state of Maine, a short-range region, an intermediate region, and a long-range region. We considered variables that represented potential gypsy moth movement pathways within each region, including transportation networks, recreational activities, urban characteristics, and household movement data originating from gypsy moth infested areas (U.S. Postal Service address forwarding data). We updated the models annually, linked the models to an early detection survey design, and validated the models for the following year using predicted risk at new positive detection locations. Human-assisted pathways data, such as address forwarding, became increasingly important predictors of gypsy moth detection in the intermediate-range geographic model as more predictor data accumulated over time (relative importance = 5.9%, 17.36%, and 35.76% for 2015, 2016, and 2018, respectively). Receiver operating curves showed increasing performance for iterative annual models (area under the curve (AUC) = 0.63, 0.76, and 0.84 for 2014, 2015, and 2016 models, respectively), and boxplots of predicted risk each year showed increasing accuracy and precision of following year positive detection locations. The inclusion of human-assisted pathway predictors combined with the strategy of iterative modeling brings significant advantages to targeting early detection of invasive species. We present the first published example of iterative species distribution modeling for invasive species in an operational context.
Highlights
Effective targeting for early detection of invasive species requires knowledge of an organism’s biology and mechanisms of invasion, as well as the ability to translate that information into an optimized surveillance program [1]
Our goal is to develop a species distribution model to support the early detection of European gypsy moth that addresses geographic and temporal variability of spread mechanisms
We developed origin-destination data as a predictor for human-assisted spread, developed regionalized models based on geographic changes in predictor strength, and analyzed the value of iterative model development by assessing model performance with following year survey data
Summary
Effective targeting for early detection of invasive species requires knowledge of an organism’s biology and mechanisms of invasion, as well as the ability to translate that information into an optimized surveillance program [1]. Researchers most often define distributions by an organism’s potential niche [5], estimated by the range of abiotic variability within which it can survive and reproduce. For invasive species distribution models (iSDMs), dispersal may be assisted by human movement, which can transport organisms across long distances [12,13,14,15]. The inclusion of dispersal mechanisms or “pathways” within iSDMs may be an effective approach for optimizing early detection programs to areas with high potential for invasion [16,17,18]
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