Fredric V. Vencl, Stefan Bartram, Klaus Winter, Wilhelm Boland, Robert B. Srygley
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引用次数: 0
Abstract
Little is known about the potential responses of ecologically specialized tropical species to atmospheric change and global warming. In 2 years of greenhouse experiments simulating climate change impacts, we quantified the effects of mean ambient temperature, elevated temperature (Te), current ambient CO2 concentration ([CO2]a), and doubled CO2 concentration ([CO2]e) on biomass, growth rate, and foliar chemistry of the morning glory vine, Camonea umbellata. In addition, we measured the impacts of climate change simulations on the performance and survival of the tortoise beetle, Acromis sparsa, which feeds exclusively on C. umbellata. Full-sib A. sparsa larval broods were divided into cohorts. Each cohort was placed in one of four temperature-CO2 controlled chambers and fed leaves grown in their respective treatments. Vines growing in [CO2]e more than doubled their biomass and their leaves expanded faster. The [CO2]a and Te treatments interacted to yield the greatest foliar [C]. Vines in [CO2]e and Te had the greatest C:N ratios, the lowest availability of nitrogen, and highest larval mortality. Whereas pupae were smaller and suffered lower survival in Te, pupal mass and survival increased in both the [CO2]e and Te treatments. Overall, the simultaneous elevation of both [CO2] and temperature caused declines in host quality, larval survivorship, and pupal mortality that were not observed when only one climate factor was altered. Based on this first tropical experimental study, we predict that C. umbellata will benefit from elevation of temperature and atmospheric [CO2] by altering its foliar chemistry to the detriment of its diet-specialized herbivore enemy.
Abstract in Spanish is available with online material.
人们对具有生态特异性的热带物种对大气变化和全球变暖的潜在反应知之甚少。在为期两年的模拟气候变化影响的温室实验中,我们量化了平均环境温度、升高温度(Te)、当前环境二氧化碳浓度([CO2]a)和加倍二氧化碳浓度([CO2]e)对牵牛花藤(Camonea umbellata)的生物量、生长速度和叶片化学性质的影响。此外,我们还测量了模拟气候变化对龟甲(Acromis sparsa)的表现和存活率的影响。我们将全亲 A. sparsa 幼虫分成若干群。每群幼虫都被放入四个温度-二氧化碳控制室中的一个,并喂食在各自处理中生长的叶片。在[CO2]e中生长的藤本植物生物量增加了一倍多,叶片膨大得更快。在[CO2]a和Te处理中,叶片[C]含量最高。在[CO2]e和Te处理中,藤本植物的碳氮比最大,氮的可用性最低,幼虫死亡率最高。在 Te 处理中,蛹的体积较小,存活率较低,而在[CO2]e 和 Te 处理中,蛹的体积和存活率都有所增加。总之,[CO2]和温度同时升高会导致寄主质量、幼虫存活率和蛹死亡率下降,而只改变一个气候因子时则不会出现这种情况。根据这项首次热带实验研究,我们预测伞形科昆虫将从温度和大气[CO2]的升高中获益,改变其叶面化学成分,从而损害其食性专一的食草动物敌害。 西班牙文可在线查阅。
期刊介绍:
Ranked by the ISI index, Biotropica is a highly regarded source of original research on the ecology, conservation and management of all tropical ecosystems, and on the evolution, behavior, and population biology of tropical organisms. Published on behalf of the Association of Tropical Biology and Conservation, the journal''s Special Issues and Special Sections quickly become indispensable references for researchers in the field. Biotropica publishes timely Papers, Reviews, Commentaries, and Insights. Commentaries generate thought-provoking ideas that frequently initiate fruitful debate and discussion, while Reviews provide authoritative and analytical overviews of topics of current conservation or ecological importance. The newly instituted category Insights replaces Short Communications.