Duffy-Anderson Janet T, Stabeno Phyllis J, Siddon Elizabeth C, Andrews Alex G, Cooper Daniel W, Eisner Lisa B, Farley Edward V, Harpold Colleen E, Heintz Ron A, Kimmel David G, Sewall Fletcher F, Spear Adam H, Yasumishii Ellen C
Alaska Fisheries Science Center, NOAA, National Marine Fisheries Service, Seattle, Washington, United States of America.
Pacific Marine Environmental Laboratory, Seattle, WA, United States of America.
PLoS One. 2017 Jun 28;12(6):e0178955. doi: 10.1371/journal.pone.0178955. eCollection 2017.
In 2014, the Bering Sea shifted back to warmer ocean temperatures (+2 oC above average), bringing concern for the potential for a new warm stanza and broad biological and ecological cascading effects. In 2015 and 2016 dedicated surveys were executed to study the progression of ocean heating and ecosystem response. We describe ecosystem response to multiple, consecutive years of ocean warming and offer perspective on the broader impacts. Ecosystem changes observed include reduced spring phytoplankton biomass over the southeast Bering Sea shelf relative to the north, lower abundances of large-bodied crustacean zooplankton taxa, and degraded feeding and body condition of age-0 walleye pollock. This suggests poor ecosystem conditions for young pollock production and the risk of significant decline in the number of pollock available to the pollock fishery in 2-3 years. However, we also noted that high quality prey, large copepods and euphausiids, and lower temperatures in the north may have provided a refuge from poor conditions over the southern shelf, potentially buffering the impact of a sequential-year warm stanza on the Bering Sea pollock population. We offer the hypothesis that juvenile (age-0, age-1) pollock may buffer deleterious warm stanza effects by either utilizing high productivity waters associated with the strong, northerly Cold Pool, as a refuge from the warm, low production areas of the southern shelf, or by exploiting alternative prey over the southern shelf. We show that in 2015, the ocean waters influenced by spring sea ice (the Cold Pool) supported robust phytoplankton biomass (spring) comprised of centric diatom chains, a crustacean copepod community comprised of large-bodied taxa (spring, summer), and a large aggregation of midwater fishes, potentially young pollock. In this manner, the Cold Pool may have acted as a trophic refuge in that year. The few age-0 pollock occurring over the southeast shelf consumed high numbers of euphausiids which may have provided a high quality alternate prey. In 2016 a retracted Cold Pool precluded significant refuging in the north, though pollock foraging on available euphausiids over the southern shelf may have mitigated the effect of warm waters and reduced large availability of large copepods. This work presents the hypothesis that, in the short term, juvenile pollock can mitigate the drastic impacts of sustained warming. This short-term buffering, combined with recent observations (2017) of renewed sea ice presence over southeast Bering Sea shelf and a potential return to average or at least cooler ecosystem conditions, suggests that recent warm year stanza (2014-2016) effects to the pollock population and fishery may be mitigated.
2014年,白令海的海洋温度回升至较温暖水平(比平均温度高2摄氏度),这引发了人们对新一轮温暖期以及广泛的生物和生态级联效应的担忧。2015年和2016年开展了专门调查,以研究海洋升温进程和生态系统的响应。我们描述了生态系统对连续多年海洋变暖的响应,并探讨了更广泛的影响。观察到的生态系统变化包括:与北部相比,白令海东南部陆架春季浮游植物生物量减少;大型甲壳类浮游动物类群数量减少;0龄狭鳕的摄食和身体状况变差。这表明不利于幼鳕生长的生态系统状况,以及在未来两到三年内可供狭鳕渔业捕捞的狭鳕数量大幅下降的风险。然而,我们也注意到,北部高质量的猎物、大型桡足类和磷虾,以及较低的温度,可能为南部陆架恶劣条件提供了一个避难所,有可能缓冲连续数年温暖期对白令海狭鳕种群的影响。我们提出一个假设,即幼龄(0龄、1龄)狭鳕可能通过利用与强大的北部冷池相关的高生产力水域(作为南部陆架温暖、低生产力区域的避难所),或通过在南部陆架捕食替代猎物,来缓冲有害温暖期的影响。我们发现,2015年,受春季海冰(冷池)影响的海水支持了由中心硅藻链组成的强劲浮游植物生物量(春季)、由大型类群组成的甲壳类桡足类群落(春季、夏季),以及大量中层鱼类的聚集,可能是幼龄狭鳕。以这种方式,冷池在那一年可能起到了营养避难所的作用。在东南部陆架出现的少数0龄狭鳕大量摄食磷虾,这可能提供了高质量的替代猎物。2016年,退缩的冷池使得北部无法提供显著的避难所,不过狭鳕在南部陆架捕食现有的磷虾,可能减轻了暖水的影响,并减少了大型桡足类的大量存在。这项研究提出了一个假设,即在短期内,幼龄狭鳕可以减轻持续变暖的剧烈影响。这种短期缓冲,再加上最近(2017年)观察到白令海东南部陆架重新出现海冰,以及生态系统状况可能恢复到平均水平或至少更凉爽,这表明近期温暖年份(2014 - 2016年)对狭鳕种群和渔业的影响可能会得到缓解。
