Marine Ecology, GEOMAR Helmholtz Centre of Ocean Research Kiel, Kiel, 24105, Germany.
Faculty of Mathematics and Natural Sciences, Christian-Albrechts-University, Kiel, 24118, Germany.
Biol Rev Camb Philos Soc. 2017 May;92(2):1011-1026. doi: 10.1111/brv.12266. Epub 2016 Mar 30.
Global warming has revitalized interest in the relationship between body size and temperature, proposed by Bergmann's rule 150 years ago, one of the oldest manifestations of a 'biogeography of traits'. We review biogeographic evidence, results from clonal cultures and recent micro- and mesocosm experiments with naturally mixed phytoplankton communities regarding the response of phytoplankton body size to temperature, either as a single factor or in combination with other factors such as grazing, nutrient limitation, and ocean acidification. Where possible, we also focus on the comparison between intraspecific size shifts and size shifts resulting from changes in species composition. Taken together, biogeographic evidence, community-level experiments and single-species experiments indicate that phytoplankton average cell sizes tend to become smaller in warmer waters, although temperature is not necessarily the proximate environmental factor driving size shifts. Indirect effects via nutrient supply and grazing are important and often dominate. In a substantial proportion of field studies, resource availability is seen as the only factor of relevance. Interspecific size effects are greater than intraspecific effects. Direct temperature effects tend to be exacerbated by indirect ones, if warming leads to intensified nutrient limitation or copepod grazing while ocean acidification tends to counteract the temperature effect on cell size in non-calcifying phytoplankton. We discuss the implications of the temperature-related size trends in a global-warming context, based on known functional traits associated with phytoplankton size. These are a higher affinity for nutrients of smaller cells, highest maximal growth rates of moderately small phytoplankton (ca. 10 µm ), size-related sensitivities for different types of grazers, and impacts on sinking rates. For a phytoplankton community increasingly dominated by smaller algae we predict that: (i) a higher proportion of primary production will be respired within the microbial food web; (ii) a smaller share of primary production will be channeled to the classic phytoplankton - crustacean zooplankton - fish food chain, thus leading to decreased ecological efficiency from a fish-production point of view; (iii) a smaller share of primary production will be exported through sedimentation, thus leading to decreased efficiency of the biological carbon pump.
全球变暖重新激发了人们对体型与温度之间关系的兴趣,这一关系早在 150 年前就由伯格曼法则提出,是“性状生物地理学”最古老的表现形式之一。我们综述了生物地理学方面的证据、克隆培养的结果以及最近关于自然混合浮游植物群落的微宇宙和中宇宙实验的结果,这些实验研究了浮游植物体型对温度的响应,无论是作为单一因素还是与其他因素(如摄食、营养限制和海洋酸化)相结合。在可能的情况下,我们还重点比较了种内体型变化与由物种组成变化引起的体型变化。总的来说,生物地理学方面的证据、群落水平的实验以及单一物种的实验表明,浮游植物的平均细胞大小往往会随着水温升高而变小,尽管温度不一定是驱动体型变化的直接环境因素。通过营养供应和摄食的间接效应很重要,而且通常占主导地位。在很大一部分实地研究中,资源可利用性被视为唯一相关的因素。种间体型效应大于种内效应。如果变暖导致营养限制加剧或桡足类动物摄食增加,那么直接的温度效应往往会被间接的温度效应放大,而海洋酸化则倾向于抵消非钙化浮游植物中细胞大小对温度的影响。我们根据与浮游植物体型相关的已知功能特征,讨论了在全球变暖背景下与温度相关的体型趋势的影响。这些特征包括:更小的细胞对营养物质的亲和力更高,中等大小的浮游植物(约 10 µm)具有最高的最大生长率,不同类型的捕食者与体型相关的敏感性,以及对沉降率的影响。对于一个越来越由小型藻类主导的浮游植物群落,我们预计:(i)微生物食物网中呼吸作用的初级生产力比例将更高;(ii)经典的浮游植物-桡足类动物-鱼类食物链中初级生产力的份额将会减少,因此从鱼类生产的角度来看,生态效率将会降低;(iii)通过沉降而输出的初级生产力的份额将会减少,因此生物碳泵的效率将会降低。
