Insect size responses to climate change vary across elevations according to seasonal timing.

IF 9.8 1区生物学 Q1 Agricultural and Biological Sciences

PLoS Biology Pub Date : 2025-01-30 eCollection Date: 2025-01-01 DOI:10.1371/journal.pbio.3002805

César R Nufio, Monica M Sheffer, Julia M Smith, Michael T Troutman, Simran J Bawa, Ebony D Taylor, Sean D Schoville, Caroline M Williams, Lauren B Buckley

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引用次数: 0

Abstract

Body size declines are a common response to warming via both plasticity and evolution, but variable size responses have been observed for terrestrial ectotherms. We investigate how temperature-dependent development and growth rates in ectothermic organisms induce variation in size responses. Leveraging long-term data for six montane grasshopper species spanning 1,768-3 901 m, we detect size shifts since ~1960 that depend on elevation and species' seasonal timing. Size shifts have been concentrated at low elevations, with the early emerging species (those that overwinter as juveniles) increasing in size, while later season species are becoming smaller. Interannual temperature variation accounts for the size shifts. The earliest season species may be able to take advantage of warmer conditions accelerating growth during early spring development, whereas warm temperatures may adversely impact later season species via mechanisms such as increased rates of energy use or thermal stress. Grasshoppers tend to capitalize on warm conditions by both getting bigger and reaching adulthood earlier. Our analysis further reinforces the need to move beyond expectations of universal responses to climate change to consider how environmental exposure and sensitivity vary across elevations and life histories.

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昆虫大小对气候变化的响应因季节而异。

体型下降是通过可塑性和进化对变暖的共同反应，但在陆生变温动物中观察到体型变化的反应。我们研究了恒温生物的温度依赖性发育和生长速率如何诱导大小响应的变化。利用跨越1768 - 3901 m的6种山地蚱蜢的长期数据，我们检测了自1960年以来依赖于海拔和物种季节时间的大小变化。尺寸变化集中在低海拔地区，早期出现的物种（幼年越冬的物种）尺寸增加，而晚季物种尺寸变小。年际温度变化解释了大小变化。早季物种可能能够利用温暖的条件在早春发育期间加速生长，而温暖的温度可能通过增加能量利用率或热应激等机制对晚季物种产生不利影响。蚱蜢倾向于利用温暖的环境，长得更大，更早成年。我们的分析进一步强调，有必要超越对气候变化的普遍反应的期望，考虑不同海拔和生活史的环境暴露和敏感性如何变化。

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

PLoS Biology BIOCHEMISTRY & MOLECULAR BIOLOGY-BIOLOGY

CiteScore

15.40

自引率

2.00%

发文量

359

审稿时长

3-8 weeks

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