Response of daily increment of statolith of neon flying squid (Ommastrephes bartramii) for different cohorts to marine environment in the North Pacific
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摘要: 为了研究北太平洋柔鱼(Ommastrephes bartramii)索饵场不同群体耳石日增量与环境之间的关系,采用梯度森林法和广义加性模型对2010−2016年在北太平洋采集的柔鱼进行了耳石日增量与海洋环境间的关系的分析。结果表明,柔鱼生命周期大约为1 a,秋生群体柔鱼个体的日龄范围为165~345 d,冬春生群体柔鱼个体的日龄范围为95~271 d。100 m水层海水温度、海表面温度、海表面盐度和混合层深度是影响柔鱼秋生群体耳石日生长的关键环境变量;100 m水层海水温度、海表面高度和叶绿素浓度是影响冬春生群体耳石日生长的关键环境变量。广义加性模型分析表明,耳石日增量宽度与梯度森林法筛选的关键环境变量存在显著关系(p <0.01)。不同群体的关键环境变量表明,温度和饵料丰度的变化对柔鱼生长有着显著的影响。Abstract: In order to study the relationship between daily increment of statolith and environment of neon flying squid (Ommastrephes bartramii) for different cohorts in the North Pacific during feeding ground, we explore the relationship between daily increment of statolith microstructure and environmental variables by gradient forest method (GFM) and generalized additive model (GAM) based on the samples collected in the North Pacific from 2010 to 2016. The results show that the life cycle of O. bartramii is about one year. The age of the autumn cohort ranges from 165 d to 345 d, and the age of winter-spring cohort ranges from 95 d to 271 d, respectively. Sea water temperature at the depth of 100 m (Temp_100), sea surface temperature (SST), sea surface salinity (SSS) and mixed layer depth (MLD) are the key environmental variables for the daily growth of autumn cohort. Temp_100, MLD, sea surface height (SSH) and chlorophyll a concentration (CHL) are the key environment variables for the daily growth of winter-spring cohort. GAM analysis shows that the daily increment width of statolith is significantly correlated with the key environmental variables selected by GFM (p<0.01). Key environmental variables of different cohorts suggest that the growth of O.bartrarnii is significantly affected by water temperature and prey abundance.
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图 1 北太平洋柔鱼采样站点
Fig. 1 Sampling stations of Ommastrephes bartramii in the North Pacific
图 2 北太平洋柔鱼采样区域与研究区域
Fig. 2 Sampling area and study area of Ommastrephes bartramii in the North Pacific
图 3 柔鱼耳石微结构及日龄、日增量测量方向
Fig. 3 Microstructure of statolith and measurement direction of age and daily increment for Ommastrephes bartramii
图 4 不同群体柔鱼的耳石平均日增量宽度
a. 秋生群体;b. 冬春生群体
Fig. 4 Mean daily increment width of statolith of Ommastrephes bartramii for different cohorts
a. Autumn cohort; b. winter-spring cohort
图 5 不同群体柔鱼耳石平均日增量宽度分布
Fig. 5 Distribution of mean daily increment width of statolith of Ommastrephes bartramii for different cohorts
图 6 环境变量对不同群体柔鱼耳石平均日增量宽度的权重
a. 秋生群体;b. 冬春生群体
Fig. 6 Weight of environmental variables on statolith mean daily increment width of Ommastrephes bartramii for different cohorts
a. Autumn cohort; b. winter-spring cohort
图 7 不同环境因子对秋生群体(a1−a4)和冬春生群体(b1−b4)柔鱼耳石日增量宽度的累积重要性
Fig. 7 Cumulative importance of different environmental factors in relation to daily increment width of statolith of Ommastrephes bartramii for autumn cohort (a1−a4) and winter-spring cohort (b1−b4)
图 8 基于GAM的关键环境变量对秋生群体(a1−a4)和冬春生群体(b1−b4)柔鱼耳石平均日增量宽度的影响
Fig. 8 Effective of key environment variables on mean daily increment width of Ommastrephes bartramii for autumn cohort (a1−a4) and winter-spring cohort (b1−b4) based on GAM
图 9 不同群体柔鱼索饵场100 m水层水温分布
a. 秋生群体;b. 冬春生群体
Fig. 9 Distribution of Temp_100 for different cohorts of Ommastrephes bartramii in feeding ground
a. Autumn cohort; b. winter-spring cohort
表 1 北太平洋柔鱼样本基本信息
Tab. 1 Basic information of Ommastrephes bartramii in the North Pacific
海域 月份 数量/尾 日龄/d 孵化高峰期 胴长/mm 东部海域 5−6月 188 165~345 8−10月 200~501 西部海域 7−10月 221 95~271 2−4月 162~345 
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表 2 关键环境变量对柔鱼耳石日增量宽度的GAM分析
Tab. 2 The key environment variables on daily increment width in Ommastrephes bartramii based on the generalized additive model (GAM) analyses
群体 环境变量 偏差解释率/% AIC R2 F p 显著性 秋生群体 Temp_100 96.2 −401.704 5 0.958 217.2 <0.000 1 *** SST 94.1 −363.818 1 0.935 136.7 <0.000 1 *** SSS 92.4 −348.225 3 0.919 144.5 <0.000 1 *** MLD 88.7 −317.438 0.882 134.8 <0.000 1 *** 冬春生群体 Temp_100 92.6 −519.3610 0.921 179.2 <0.000 1 *** MLD 75.2 −359.568 4 0.741 59.43 <0.000 1 *** SSH 56 −284.356 8 0.547 34.95 <0.000 1 *** CHL 51.5 −269.784 2 0.498 25.09 <0.000 1 *** 注:*** (p<0.000 1)。
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