Abstract
ABSTRACT Species distribution modeling (SDM) studies of aquatic macrophytes are still attached to methodological paradigms focused on terrestrial plants, such as the use of bioclimatic layers. Our goal was to evaluate the applicability of this paradigm based on a SDM study of Egeria densa, Pontederia crassipes, and Salvinia auriculata in the Sao Francisco river, Brazil. We compared performances of optimizations of computed models using AUC and TSS with distribution records of these species and bioclimatic layers, or limnological layers generated from the interpolation of data obtained in the field. We calculated models using six algorithms. The models calculated using layers of limnological variables had higher performances than did those calculated using layers of bioclimatic variables, except when the Maximum Entropy Default algorithm was used. We attribute these results to the specificities of the data obtained to develop the limnological layers, such as observations obtained in different habitats of the river and during different hydrologic periods. We conclude that the use of bioclimatic layers, a methodological paradigm traditionally used for SDM of aquatic macrophytes, can be questionable for some situations, such as in investigations at local and regional scales.
Highlights
Species distribution modeling (SDM), known as ecological niche modeling or habitat suitability modeling, is a method that employs mathematical algorithms to correlate distribution records of one or more species with environmental conditions
Analysis of the models calculated for each algorithm revealed that the results for Area Under the Curve (AUC) and/or True Skill Statistic (TSS) from the model optimizations of models calculated for each species using Maximum Entropy Default (MXD) diverged from those obtained using the other algorithms (Tab. 1)
The models calculated for each species using layers of limnological variables had higher performances than those calculated using layers of bioclimatic variables, except for models calculated with the MXD algorithm (Tab. 1)
Summary
Species distribution modeling (SDM), known as ecological niche modeling or habitat suitability modeling, is a method that employs mathematical algorithms to correlate distribution records of one or more species with environmental conditions (e.g., bioclimatic). The use of SDM allows researchers to analyze complex non-linear data, with interactions and incomplete data, for several ecological applications, such as (i) planning biodiversity conservation strategies; (ii) predicting the impacts of future climate change on species and communities; and (iii) managing biological invasions (Miller 2010; Elith & Franklin 2013) Along with these broad SDM applications, researchers have gradually increased their focus on the precision and uncertainty of species predictions (Segurado & Araujo 2004; Guo et al 2015; Barbet-Massin et al 2018). Studies have indicated that planning SDM requires biological knowledge of the target species, careful selection of distribution records and environmental variables, choosing an adequate algorithm for the application of the model or the number of distribution records (De Marco Jr. & Siqueira 2009; Miller 2010; Kamino et al 2011; Elith & Franklin 2013)
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