Shifting precipitation regimes alter the phenology and population dynamics of low latitude ectotherms

Erica H. Henry , Adam J. Terando , William F. Morris , Jaret C. Daniels , Nick M. Haddad
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Abstract

Predicting how species respond to changes in climate is critical to conserving biodiversity. Modeling efforts to date have largely centered on predicting the effects of warming temperatures on temperate species phenology. In and near the tropics, the effects of a warming planet on species phenology are more likely to be driven by changes in the seasonal precipitation cycle rather than temperature. To demonstrate the importance of considering precipitation-driven phenology in ecological studies, we present a case study wherein we construct a mechanistic population model for a rare subtropical butterfly (Miami blue butterfly, Cyclargus thomasi bethunebakeri) and use a suite of global climate models to project butterfly populations into the future. Across all iterations of the model, the trajectory of Miami blue populations is uncertain. We identify both biological uncertainty (unknown diapause survival rate) and climate uncertainty (ambiguity in the sign of precipitation change across climate models), and their interaction as key factors that determine persistence vs. extinction. Despite uncertainty, the most optimistic iteration of the model predicts that Miami blue butterfly populations will decline under the higher emissions scenario (RCP 8.5). The lack of climate model agreement across the projection ensemble suggests that investigations into the effect of climate change on precipitation-driven phenology require a higher level of rigor in the uncertainty analysis compared to analogous studies of temperature. For tropical species, a mechanistic approach that incorporates both biological and climate uncertainty is the best path forward to understand the effect shifting precipitation regimes have on phenology and population dynamics.

降水变化改变了低纬度变温动物的物候和种群动态
预测物种如何应对气候变化对保护生物多样性至关重要。迄今为止,建模工作主要集中在预测温度变暖对温带物种物候的影响。在热带及其附近,地球变暖对物种物候的影响更有可能是由季节性降水周期的变化而不是温度驱动的。为了证明考虑降水驱动物候在生态学研究中的重要性,我们提出了一个案例研究,其中我们为一种稀有的亚热带蝴蝶(迈阿密蓝蝴蝶,Cyclargus thomasi bethunebakeri)构建了一个机制种群模型,并使用一套全球气候模型来预测蝴蝶种群的未来。在模型的所有迭代中,迈阿密蓝种群的轨迹是不确定的。我们确定了生物不确定性(未知的滞育存活率)和气候不确定性(气候模型中降水变化标志的模糊性),以及它们之间的相互作用是决定持久性与灭绝的关键因素。尽管存在不确定性,但该模型最乐观的迭代预测,在较高排放情景(RCP 8.5)下,迈阿密蓝蝴蝶的数量将下降。在整个预估集合中缺乏气候模式一致性表明,与类似的温度研究相比,研究气候变化对降水驱动物候的影响需要在不确定性分析中具有更高的严谨性。对于热带物种来说,结合生物和气候不确定性的机制方法是了解降水变化对物候和种群动态影响的最佳途径。
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