Before the brink: considering sublethal impacts of climate change on stingless bee flight performance

IF 2.9 2区生物学 Q2 BIOLOGY

Journal of thermal biology Pub Date : 2025-10-01 DOI:10.1016/j.jtherbio.2025.104286

Carmen Rose Burke da Silva , Lachlan David Macnaughtan , Oliver William Griffith , Ajay Narendra

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Abstract

Vulnerability to climate change is often predicted using species critical thermal limits (CT_MAX), the temperature at which an organism experiences a loss of physiological function. However, climate change will impact species physiological traits, behaviour, reproduction, and phenology before their critical thermal limits are reached. Thermal performance curves (TPCs) are one way to evaluate how temperature impacts ecologically relevant traits before species reach their upper thermal limits. Comparing species TPCs to the climatic conditions they experience through their geographic ranges can provide insights into how vulnerable species are to further climate change and how their ranges might be altered. We assessed how flight performance – an important trait for escaping predators, dispersing, and finding resources and mates – is affected by temperature in two agriculturally important species of native stingless bees, Austroplebeia australis and Tetragonula carbonaria. A. australis has a broad arid/tropical geographic range and T. carbonaria has a narrower coastal subtropical range. We tested the thermal flight performance of both species at seven distinct temperatures between 18 and 42 °C. A. australis had a broader TPC and higher thermal optima than T. carbonaria reflecting the broader range of environmental temperatures and the hotter average environmental conditions they experience across their range. However, while A. australis could maintain flight performance at hotter temperatures, a larger proportion of their range is hotter than their thermal optima, suggesting their geographic range might constrict prior to the range of T. carbonaria.

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在边缘之前：考虑气候变化对无刺蜜蜂飞行性能的亚致命影响。

对气候变化的脆弱性通常使用物种临界热极限（CTMAX）来预测，该温度是生物体经历生理功能丧失的温度。然而，在物种达到临界温度极限之前，气候变化会影响物种的生理特征、行为、繁殖和物候。热性能曲线（TPCs）是在物种达到其热上限之前评估温度如何影响生态相关性状的一种方法。将物种tpc与它们在地理范围内所经历的气候条件进行比较，可以深入了解物种对进一步气候变化的脆弱性，以及它们的生存范围可能会如何改变。我们评估了两种农业上重要的原生无刺蜜蜂——austropplebeia australis和Tetragonula carbonaria——的飞行性能是如何受到温度的影响的。飞行性能是逃避捕食者、分散、寻找资源和配偶的重要特征。南方稻属有广阔的干旱/热带地理分布范围，而炭黑稻属有较窄的沿海亚热带分布范围。我们在18至42°C之间的7种不同温度下测试了这两种物种的热飞行性能。南方古猿的TPC范围较宽，热最优值高于炭黑古猿，这反映了它们所经历的环境温度范围更广，平均环境条件也更热。然而，尽管南方南方古猿可以在更高的温度下保持飞行性能，但它们的活动范围中有更大比例的温度高于它们的热最佳状态，这表明它们的地理范围可能比炭黑古猿更早收缩。

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

Journal of thermal biology 生物-动物学

CiteScore

5.30

自引率

7.40%

发文量

196

审稿时长

14.5 weeks

期刊介绍： The Journal of Thermal Biology publishes articles that advance our knowledge on the ways and mechanisms through which temperature affects man and animals. This includes studies of their responses to these effects and on the ecological consequences. Directly relevant to this theme are: • The mechanisms of thermal limitation, heat and cold injury, and the resistance of organisms to extremes of temperature • The mechanisms involved in acclimation, acclimatization and evolutionary adaptation to temperature • Mechanisms underlying the patterns of hibernation, torpor, dormancy, aestivation and diapause • Effects of temperature on reproduction and development, growth, ageing and life-span • Studies on modelling heat transfer between organisms and their environment • The contributions of temperature to effects of climate change on animal species and man • Studies of conservation biology and physiology related to temperature • Behavioural and physiological regulation of body temperature including its pathophysiology and fever • Medical applications of hypo- and hyperthermia Article types: • Original articles • Review articles