Harvard John A. Paulson School of Engineering and Applied Science , Harvard University , Cambridge , Massachusetts 02138 , United States.
State Key Laboratory of Ore Deposit Geochemistry , Institute of Geochemistry, Chinese Academy of Sciences , Guiyang 550002 , China.
Environ Sci Technol. 2018 Jun 5;52(11):6256-6264. doi: 10.1021/acs.est.7b06429. Epub 2018 May 24.
Pelagic ecosystems are changing due to environmental and anthropogenic forces, with uncertain consequences for the ocean's top predators. Epipelagic and mesopelagic prey resources differ in quality and quantity, but their relative contribution to predator diets has been difficult to track. We measured mercury (Hg) stable isotopes in young (<2 years old) Pacific bluefin tuna (PBFT) and their prey species to explore the influence of foraging depth on growth and methylmercury (MeHg) exposure. PBFT total Hg (THg) in muscle ranged from 0.61 to 1.93 μg g dw (1.31 μg g dw ±0.37 SD; 99% ± 6% MeHg) and prey ranged from 0.01 to 1.76 μg g dw (0.13 μg g dw ±0.19 SD; 85% ± 18% MeHg). A systematic decrease in prey δHg and ΔHg with increasing depth of occurrence and discrete isotopic signatures of epipelagic prey (δHg: 0.74 to 1.49‰; ΔHg: 1.76-2.96‰) and mesopelagic prey (δHg: 0.09 to 0.90‰; ΔHg: 0.62-1.95‰) allowed the use of Hg isotopes to track PBFT foraging depth. An isotopic mixing model was used to estimate the dietary proportion of mesopelagic prey in PBFT, which ranged from 17% to 55%. Increased mesopelagic foraging was significantly correlated with slower growth and higher MeHg concentrations in PBFT. The slower observed growth rates suggest that prey availability and quality could reduce the production of PBFT biomass.
由于环境和人为因素的影响,远洋生态系统正在发生变化,这对海洋顶级捕食者产生了不确定的影响。表水层和中层水层的猎物资源在质量和数量上存在差异,但它们对捕食者饮食的相对贡献一直难以追踪。我们测量了幼龄(<2 岁)太平洋蓝鳍金枪鱼(PBFT)及其猎物物种的汞(Hg)稳定同位素,以探讨觅食深度对生长和甲基汞(MeHg)暴露的影响。PBFT 肌肉中的总汞(THg)范围为 0.61-1.93μg g dw(1.31μg g dw±0.37 SD;99%±6% MeHg),而猎物的 THg 范围为 0.01-1.76μg g dw(0.13μg g dw±0.19 SD;85%±18% MeHg)。随着出现深度的增加,猎物的 δHg 和 ΔHg 呈系统下降趋势,且表水层猎物(δHg:0.74-1.49‰;ΔHg:1.76-2.96‰)和中层水层猎物(δHg:0.09-0.90‰;ΔHg:0.62-1.95‰)具有离散的同位素特征,这使得可以利用 Hg 同位素追踪 PBFT 的觅食深度。同位素混合模型用于估计 PBFT 中中层水层猎物的饮食比例,范围为 17%-55%。中层水层觅食的增加与 PBFT 生长速度较慢和 MeHg 浓度较高显著相关。观察到的生长速度较慢表明,猎物的可利用性和质量可能会降低 PBFT 生物量的产生。
