Hot, dry, and salty: The present and future of an Extremophile model lizard from Argentina

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Rafael A. Lara-Reséndiz , José M. Sánchez , Romina S. Paez , Suelem Muñiz-Leão , Guarino R. Colli , Donald B. Miles , Barry Sinervo , Nicolás Pelegrin
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Abstract

Global warming poses a threat to lizard populations by raising ambient temperatures above historical norms and reducing thermoregulation opportunities. Whereas the reptile fauna of desert systems is relatively well studied, the lizard fauna of saline environments has not received much attention and—to our knowledge—thermal ecology and the effects of global warming on lizards from saline environments have not been yet addressed. This pioneer study investigates the thermal ecology, locomotor performance and potential effects of climate warming on Liolaemus ditadai, a lizard endemic to one of the largest salt flats on Earth. We sampled L. ditadai using traps and active searches along its known distribution, as well as in other areas within Salinas Grandes and Salinas de Ambargasta, where the species had not been previously recorded. Using ensemble models (GAM, MARS, RandomForest), we modeled climatically suitable habitats for L. ditadai in the present and under a pessimistic future scenario (SSP585, 2070). L. ditadai emerges as an efficient thermoregulator, tolerating temperatures near its upper thermal limits. Our ecophysiological model suggests that available activity hours predict its distribution, and the projected temperature increase due to global climate change should minimally impact its persistence or may even have a positive effect on suitable thermal habitat. However, this theoretical increase in habitat could be linked to the distribution of halophilous scrub in the future. Our surveys reveal widespread distribution along the borders of Salinas Grandes and Salinas de Ambargasta, suggesting a potential presence along the entire border of both salt plains wherever halophytic vegetation exists. Optimistic model results, extended distribution, and no evidence of flood-related adverse effects offer insights into assessing the conservation status of L. ditadai, making it and the Salinas Grandes system suitable models for studying lizard ecophysiology in largely unknown saline environments.

热、干、咸:阿根廷嗜极模式蜥蜴的现状与未来。
全球变暖使环境温度超过历史标准,减少了体温调节机会,从而对蜥蜴种群构成威胁。虽然对沙漠地区爬行动物的研究相对较多,但对盐碱环境中蜥蜴动物的研究却不多,而且据我们所知,热生态学和全球变暖对盐碱环境中蜥蜴的影响尚未得到研究。这项开创性的研究调查了Liolaemus ditadai的热生态学、运动性能和气候变暖的潜在影响,Liolaemus ditadai是地球上最大的盐滩之一特有的蜥蜴。我们在 Liolaemus ditadai 的已知分布区以及 Salinas Grandes 和 Salinas de Ambargasta 的其他地区使用诱捕器和主动搜索对其进行了采样,这些地区以前没有记录过该物种。利用集合模型(GAM、MARS、RandomForest),我们模拟了目前和未来悲观情景(SSP585,2070 年)下适合 L. ditadai 的气候栖息地。L. ditadai 是一种高效的温度调节器,可以耐受接近其温度上限的温度。我们的生态生理学模型表明,可利用的活动时间可预测其分布,而全球气候变化导致的预计温度升高对其持久性的影响应该很小,甚至可能对适宜的热栖息地产生积极影响。不过,理论上栖息地的增加可能与未来嗜卤灌丛的分布有关。我们的调查显示,嗜卤灌丛广泛分布于大盐湖和安巴加斯塔盐湖的边界地区,这表明只要存在嗜卤植被,嗜卤灌丛就有可能出现在这两个盐原的整个边界地区。乐观的模型结果、广泛的分布以及没有证据表明与洪水有关的不利影响,为评估 L. ditadai 的保护状况提供了启示,使它和格兰德斯盐湖系统成为在基本未知的盐碱环境中研究蜥蜴生态生理学的合适模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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