Assessing the Impacts of Climate Change on the At-Risk Species Anaxyrus microscaphus (The Arizona Toad): A Local and Range-Wide Habitat Suitability Analysis

IF 1.7 Q3 ECOLOGY
Ecologies Pub Date : 2023-12-13 DOI:10.3390/ecologies4040050
Sam M. Driver, Cord B. Eversole, Daniel R. Unger, D. Kulhavy, Christopher M. Schalk, I-Kuai Hung
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Abstract

Anaxyrus microscaphus (The Arizona Toad) is an at-risk species that is endemic to the southwestern United States. Despite conservation concerns, little is known about the ecological drivers of its distribution and habitat use. We investigated the potential distribution of A. microscaphus at the range-wide scale and local scales (i.e., Zion National Park), using MaxEnt to model habitat suitability under current and future climate scenarios. Our models incorporated 12 environmental variables, including climatic, geomorphological, and remotely sensed data. The results showed good model accuracy, with temperature and elevation being the top contributing variables. Currently, 42.6% of the park’s area provides a suitable habitat for A. microscaphus, but projections for 2050 and 2070 indicate a significant reduction in suitable habitat across its range. Temperature was the most influential variable, with habitat suitability decreasing as the annual mean temperatures exceeded 10 °C. Precipitation, vegetation, and topography variables also significantly contributed to the models. The most suitable habitat within Zion National Park occurred along sloped rivers and streams and in valleys with sandy soils, emphasizing the importance of riparian habitat conservation for A. microscaphus survival and persistence. As climate change progresses, the species’ habitat is expected to become increasingly constrained across local and range-wide scales. Our models demonstrated a shift in the suitable habitat towards major river systems, indicating a potential reliance on larger permanent river systems as smaller, more ephemeral habitats decrease in size and abundance. Future management strategies should prioritize conserving and enhancing the resilience of these habitats. MaxEnt models can guide population survey efforts and facilitate the identification of priority conservation areas, saving time and resources for species of concern such as A. microscaphus. Further research, including field surveys and large-scale analyses, is necessary to further refine our understanding of this species’ distribution and how it may be impacted by climate and habitat change.
评估气候变化对高危物种 Anaxyrus microscaphus(亚利桑那蟾蜍)的影响:地方和整个范围的栖息地适宜性分析
Anaxyrus microscaphus(亚利桑那蟾蜍)是美国西南部特有的濒危物种。尽管保护问题备受关注,但人们对其分布和栖息地利用的生态驱动因素知之甚少。我们利用 MaxEnt 对当前和未来气候情景下的栖息地适宜性进行建模,调查了 A. microscaphus 在整个分布范围和局部范围(如锡安国家公园)的潜在分布情况。我们的模型纳入了 12 个环境变量,包括气候、地貌和遥感数据。结果表明,模型的准确性很高,温度和海拔是最大的贡献变量。目前,公园 42.6% 的面积为微囊蚁提供了合适的栖息地,但对 2050 年和 2070 年的预测表明,微囊蚁整个栖息地范围内的合适栖息地将大幅减少。温度是影响最大的变量,年平均气温超过 10 °C,栖息地适宜性就会下降。降水、植被和地形变量对模型的影响也很大。锡安国家公园内最适宜的栖息地位于倾斜的河流和溪流沿岸以及沙质土壤的山谷中,这强调了保护河岸栖息地对微小蛙生存和持久性的重要性。随着气候变化的加剧,预计该物种的栖息地在当地和整个分布区范围内都将受到越来越多的限制。我们的模型显示,适宜的栖息地正在向主要河流系统转移,这表明随着更小、更短暂的栖息地面积和数量的减少,该物种可能会依赖于更大的永久性河流系统。未来的管理策略应优先考虑保护和提高这些栖息地的恢复能力。MaxEnt 模型可以为种群调查工作提供指导,并有助于确定优先保护区域,从而为微囊鲤等受关注物种节省时间和资源。我们有必要开展进一步的研究,包括实地调查和大规模分析,以进一步了解该物种的分布情况以及气候和栖息地变化可能对其产生的影响。
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CiteScore
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