Projecting the compound effects of climate change and white-nose syndrome on North American bat species

Meredith L. McClure , Carter R. Hranac , Catherine G. Haase , Seth McGinnis , Brett G. Dickson , David T.S. Hayman , Liam P. McGuire , Cori L. Lausen , Raina K. Plowright , N. Fuller , Sarah H. Olson
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Abstract

Climate change and disease are threats to biodiversity that may compound and interact with one another in ways that are difficult to predict. White-nose syndrome (WNS), caused by a cold-loving fungus (Pseudogymnoascus destructans), has had devastating impacts on North American hibernating bats, and impact severity has been linked to hibernaculum microclimate conditions. As WNS spreads across the continent and climate conditions change, anticipating these stressors’ combined impacts may improve conservation outcomes for bats. We build on the recent development of winter species distribution models for five North American bat species, which used a hybrid correlative-mechanistic approach to integrate spatially explicit winter survivorship estimates from a bioenergetic model of hibernation physiology. We apply this bioenergetic model given the presence of P. destructans, including parameters capturing its climate-dependent growth as well as its climate-dependent effects on host physiology, under both current climate conditions and scenarios of future climate change. We then update species distribution models with the resulting survivorship estimates to predict changes in winter hibernacula suitability under future conditions. Exposure to P. destructans is generally projected to decrease bats’ winter occurrence probability, but in many areas, changes in climate are projected to lessen the detrimental impacts of WNS. This rescue effect is not predicted for all species or geographies and may arrive too late to benefit many hibernacula. However, our findings offer hope that proactive conservation strategies to minimize other sources of mortality could allow bat populations exposed to P. destructans to persist long enough for conditions to improve.

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预测气候变化和白鼻综合征对北美蝙蝠物种的复合影响
气候变化和疾病是对生物多样性的威胁,它们可能以难以预测的方式相互结合和相互作用。白鼻综合征(WNS)是由一种嗜冷真菌(Pseudogymnoascus destructans)引起的,它对北美冬眠的蝙蝠产生了毁灭性的影响,影响的严重程度与冬眠的小气候条件有关。随着WNS在整个大陆的传播和气候条件的变化,预测这些压力因素的综合影响可能会改善蝙蝠的保护结果。我们基于最近发展的五种北美蝙蝠的冬季物种分布模型,该模型使用了一种混合的相关机制方法来整合来自冬眠生理学的生物能量模型的空间显式冬季生存估计。在当前气候条件和未来气候变化情景下,我们应用该生物能量模型,包括捕获其气候依赖生长及其对宿主生理的气候依赖效应的参数。然后,我们更新物种分布模型与由此产生的生存估计,以预测未来条件下冬季冬眠适应性的变化。一般预测,暴露于破坏性单胞菌会降低蝙蝠在冬季发生的概率,但在许多地区,预计气候变化会减轻破坏性单胞菌的有害影响。这种拯救效果并不适用于所有物种或地理位置,可能对许多冬眠动物来说来得太晚了。然而,我们的研究结果提供了希望,积极主动的保护策略可以最大限度地减少其他死亡来源,从而使暴露于毁灭单轴线虫的蝙蝠种群能够持续足够长的时间,以改善条件。
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