Key Laboratory of Tropical Marine Bioresources and Ecology and Guangdong Provincial Key Laboratory of Applied Marine Biology, South China Sea Institute of Oceanology, Chinese Academy of Sciences, Guangzhou, China.
Key Laboratory of Tropical Marine Bioresources and Ecology and Guangdong Provincial Key Laboratory of Applied Marine Biology, South China Sea Institute of Oceanology, Chinese Academy of Sciences, Guangzhou, China
Appl Environ Microbiol. 2019 Jan 9;85(2). doi: 10.1128/AEM.02088-18. Print 2019 Jan 15.
Thermal effluents from nuclear power plants greatly change the environmental and ecological conditions of the receiving marine water body, but knowledge about their impact on microbial ecology is limited. Here we used high-throughput sequencing of the 16S rRNA gene to examine marine bacterioplankton metacommunity assembly across thermal gradients in two representative seasons (i.e., winter and summer) in a subtropical bay located on the northern coast of the South China Sea. We found high heterogeneity in bacterioplankton community compositions (BCCs) across thermal gradients and between seasons. The spatially structured temperature gradient created by thermal effluents was the key determinant of BCCs, but its influence differed by season. Using a metacommunity approach, we found that in the thermal discharge area, i.e., where water is frequently exchanged with surrounding seawater and thermal effluent water, the BCC spatial patterns were shaped by species sorting rather than by mass effects from surrounding seawater or by dilution of thermal effluent water by surrounding seawater. However, this effect of species sorting was weaker in summer than in winter seawater. In both seasons, the bacterioplankton community structure was predominately determined by niche sharing; however, the relative importance of niche segregation was enhanced in summer seawater. Our findings suggest that for the seasonal differences in metacommunity processes, the BCCs of subtropical summer seawater were more sensitive to temperature and were more difficult to predict than those of winter seawater in the face of different intensities of thermal impacts. Understanding the mechanisms of bacterial community assembly across environmental gradients is one of the major goals of marine microbial ecology. Thermal effluents from two nuclear power plants have been present in the subtropical Daya Bay for more than 20 years and have generated a comparatively stable and long thermal gradient (a temperature increase from 0 to 10°C). The environmental patches across thermal gradients are heterogeneous and very strongly interconnected on a microbial scale; thus, this is a useful model for the study of the metacommunity processes (i.e., patch dynamics, species sorting, mass effects, and neutral processes) that underlie marine bacterioplankton assembly. The significance of our research is to reveal how environmental conditions and dispersal-related processes interact to influence bacterioplankton metacommunity processes and their seasonal differences across thermal gradients. Our results may advance the understanding of marine microbial ecology under future conditions of global warming.
核电厂的热废水会极大地改变受纳海洋水体的环境和生态条件,但人们对其对微生物生态影响的了解有限。在这里,我们使用高通量测序 16S rRNA 基因的方法,在南海北部沿岸的一个亚热带海湾的两个代表性季节(冬季和夏季)中,研究了热梯度下海洋浮游细菌的后生群集组装。我们发现,热梯度和季节之间的浮游细菌群落组成(BCC)具有很高的异质性。热废水中的空间结构温度梯度是 BCC 的关键决定因素,但这种影响因季节而异。使用后生群集方法,我们发现,在热排放区,即水经常与周围海水和热废水交换的区域,BCC 的空间格局是由物种分选而不是由周围海水的质量效应或由周围海水稀释热废水决定的。然而,这种物种分选的作用在夏季海水比冬季海水弱。在这两个季节中,浮游细菌群落结构主要由生态位共享决定;然而,在夏季海水,生态位隔离的相对重要性增强。我们的研究结果表明,对于后生群集过程的季节性差异,在面对不同强度的热影响时,亚热带夏季海水的 BCC 对温度更为敏感,也更难预测,而冬季海水的 BCC 则较为稳定。了解跨环境梯度的细菌群落组装机制是海洋微生物生态学的主要目标之一。大亚湾的两座核电站的热废水已经存在了 20 多年,产生了一个相对稳定和长的热梯度(温度从 0 增加到 10°C)。热梯度上的环境斑块是异质的,在微生物尺度上非常紧密地相互连接;因此,这是研究后生群集过程(即斑块动态、物种分选、质量效应和中性过程)的有用模型,这些过程是海洋浮游细菌组装的基础。我们研究的意义在于揭示环境条件和扩散相关过程如何相互作用,影响细菌后生群集过程及其在热梯度上的季节性差异。我们的研究结果可能会促进对全球变暖背景下海洋微生物生态学的理解。
