中西太平洋鲣栖息地指数预报模型比较研究

鲣(Katsuwonus pelamis)是太平洋热带海域重要的金枪鱼种类之一,也是目前我国金枪鱼围网渔船的主要捕捞对象之一。根据1995—2012年中西太平洋海域(5°N-10°S;125°E-135°W)延绳钓生产统计数据,结合海表面温度(SST)和海表面高度(SSH)的遥感数据,利用频次分布法分析了中西太平洋围网鲣分布的SST和SSH适宜范围;采用了外包络法,按季度分别建立了SST、SSH的适应性指数(SI),采用算术平均法(AMM)和几何平均法(GMM)建立栖息地指数(HSI)模型计算其栖息地指数,并用2013年度的捕捞数据进行验证。结果表明,中西太平洋围网鲣多分布在SST为28~30.5℃、SSH为65~95 cm的海域。以捕捞努力量(作业天数)为基础,采用外包络法建立SST、SSH的适应性指数最为合适,各个季度的SST权重分别为0.7、0.6、0.3、0.6的算数平均法适合中西太平洋围网鲣栖息地指数模型。不同季节的环境因子对中西太平洋围网鲣渔场分布有着不同的影响。     

大西洋金枪鱼延绳钓主要渔获种类及其分布

根据收集的有关文献和海上调查资料，分析了大西洋金枪鱼延绳钓生产的主要渔获品种的生物学特性、捕捞生产情况及管理措施等。此外，还根据FAO建立的金枪鱼生产数据库，采用GIS软件制作了大西洋金枪鱼延绳钓主要渔获种类捕捞产量的地理空间分布图。并分析了其资源的空间分布特征。     

Predicting the occurrence of Atlantic bluefin tuna (Thunnus thynnus) larvae in the northern Gulf of Mexico: building a classification model from archival data

Although bluefin tuna are found throughout the Atlantic Ocean, spawning in the western Atlantic has been recorded predominantly in the Gulf of Mexico (GOM) in spring. Larval bluefin tuna abundances from the northern GOM are formulated into an index used to tune the adult stock assessment, and the variability of this index is currently high. This study investigated whether some of the variability in larval bluefin tuna abundances was related to environmental conditions, by defining associations between larval bluefin tuna catch locations, and a suite of environmental variables. We hypothesized that certain habitat types, as defined by environmental variables, would be more likely to contain bluefin tuna larvae. Favorable habitat for bluefin tuna larvae was defined using a classification tree approach. Habitat within the Loop Current was generally less favorable, as were warm‐core rings, and cooler waters on the continental shelf. The location and size of favorable habitat was highly variable among years, which was reflected in the locations of larval bluefin tuna catches. The model successfully placed bluefin tuna larvae in favorable habitat with nearly 90% accuracy, but many negative stations were also located within theoretically favorable habitat. The probability of collecting larval bluefin tuna in favorable habitat was nearly twice the probability of collecting bluefin tuna larvae across all habitats (35.5 versus 21.0%). This model is a useful addition to knowledge of larval bluefin tuna distributions; however, the incorporation of variables describing finer‐scale features, such as thermal fronts, may significantly improve the model’s predictive power.     

主捕长鳍金枪鱼延绳钓钓具的最适浸泡时间

根据2012年9月21日-11月15日库克群岛海域金枪鱼延绳钓海上调查数据,建立了钓钩深度计算模型,分两种起绳方式建立了作业中每一根支绳的浸泡时间计算模型。将钓钩深度以40 m为一层,共分为6个水层(40~80 m、80~120 m、120~160 m、160~200 m、200~240 m和240~280 m),统计每个水层和整个水体内的钓钩数量和长鳍金枪鱼(Thunnus alalunga)的渔获尾数。计算每个水层和整个水体内的钓具浸泡时间,并以1 h为间隔分别统计每个区间的支绳数量及渔获尾数,计算其渔获率。结果表明:(1)二次曲线可拟合浸泡时间与长鳍金枪鱼渔获率的关系,其渔获率随浸泡时间的增加呈现先增后减的趋势;(2)长鳍金枪鱼在40~280 m整个水体、6个水层中渔获率最高的浸泡时间为11.0~11.4 h。建议:(1)主捕长鳍金枪鱼时,尽可能把支绳的浸泡时间设定在10.0~12.0 h左右,以提高捕捞效率;(2)对于漂流延绳钓,整个水体的最佳浸泡时间可代表各个水层的最佳浸泡时间;(3)目标鱼种不同,钓具的最佳浸泡时间也不同;(4)浸泡时间可作为延绳钓钓具有效捕捞努力量。研究结果可用于提高长鳍金枪鱼捕捞效率,为渔业生产和CPUE的标准化提供参考。     

酶解金枪鱼头蛋白制备羟基自由基清除物的研究

用5种蛋白酶(木瓜蛋白酶、中性蛋白酶、typsin、pepsin以及Alcalase 2.4L)分别酶解金枪鱼头蛋白,以羟基自由基清除率为指标,筛选出羟基自由基清除力最强的是Alcalase 2.4L的酶解液,通过响应面试验优化Alcalase2.4L最佳酶解条件为:酶解时间340 min,酶解温度54℃,加酶量0.38%,该条件下酶解液的羟基自由基清除率最佳,为63.67%。     

Bluefin tuna (Thunnus thynnus) distribution in relation to sea surface temperature fronts in the Gulf of Maine (1994–96)

Fishery‐linked aerial surveys for bluefin tuna (Thunnus thynnus) were conducted in the Gulf of Maine (GOM) from July through October, 1994–96. Each year, from 507 to 890 surface schools were detected and their locations examined in relation to oceanographic conditions. Correlations between bluefin tuna presence and environmental variables were explored for sea surface temperature (SST), distance to a SST front, frontal density (relative density of all SST fronts seen in a given 1 km area for 2 weeks prior to each tuna sighting), and bottom depth and slope. Mean SST associated with bluefin schools was 18.1°C (±2.8). Schools were located at a mean distance of 19.7 km (±19.6) from SST fronts, and in water masses with an average frontal density of 28.2 m km^?2 (±35.7). Mean bottom depth of detected schools was 139.0 m (±70.3), and mean bottom slope was 0.7% rise (±0.7). A binomial generalized linear model fit to these variables indicated that bluefin are seen closer to fronts than locations in which no tuna were seen. Using simple and partial Mantel tests, we investigated the spatial correlation between bluefin tuna presence and the environmental variables, controlling for spatial autocorrelation. For each day that schools were sighted, we performed 24 Mantel tests, on a combination of response and predictor variables. The spatial relationship between bluefin tuna and SST fronts was inconsistent. Our analysis identified significant spatial structure in the bluefin school locations that had no significant correlation with any of the measured environmental features, suggesting that other untested features, such as prey density, may be important predictors of bluefin distribution in the GOM.     

印度洋黄鳍金枪鱼渔业管理策略评价的初步研究

近年来印度洋黄鳍金枪鱼捕捞量一直维持在最大持续产量附近,其整体资源处于风险状态。由于渔业数据存在各种误差,渔业资源评估结果也存在很大的不确定性,传统的渔业资源管理方法会影响渔业资源的可持续利用。渔业管理策略评价是一种系统方法,通过计算机模拟管理对象的渔业系统,设定合理的管理目标,然后测试和评价不同渔业管理策略的表现,可以提高渔业管理成功的概率,在渔业中的使用也越来越广泛。本研究根据印度洋黄鳍金枪鱼的生活史特征参数和渔业数据,建立操作模型,通过计算机模拟对印度洋黄鳍金枪鱼渔业不同管理策略的结果进行评价,从而选择适宜的管理策略,为印度洋黄鳍金枪鱼资源持续发展提供建议。本研究共设置25种管理策略,通过渔业管理策略评价(management strategy evaluation,MSE),并结合各种不确定性,得到最合适的管理策略是管理策略7,即F设置为0.2,SSB设置为600 000 t。     

中西太平洋围网黄鳍金枪鱼渔场分布与溶解氧垂直结构的关系

溶解氧垂直结构是影响黄鳍金枪鱼(Thunnus albacares)垂直活动的重要因素,为了解中西太平洋围网黄鳍金枪鱼渔场溶解氧的分布特征及其对围网渔业生产的影响,基于WOA18溶解氧三维数据集和中西太平洋2008-2017年间围网黄鳍金枪鱼渔业的生产数据,分析渔场区溶解氧浓度的垂直结构特征及其与渔获量(catch p...     

Analysis of sinking death using video images of the swimming performance of Pacific Bluefin tuna (Thunnus orientalis) larvae

In this study, we aimed to clarify the mechanism of sinking death during the larval stage of Pacific Bluefin tuna Thunnus orientalis by investigating the effects of swimming performance on sinking death, using a behavioral approach. Swimming performance was examined 3–9 days after hatching (DAH) under day and night light conditions in cuboid experimental tanks. Swimming behavior variables such as swimming speed and swimming angle were measured under both light conditions. Larvae in the daytime experiment and larvae with inflated swim bladders at night were distributed on the surface layer of the water column. In contrast, larvae with uninflated swim bladders at night were frequently observed swimming vertically or sinking to the bottom of the tank. Larvae with inflated swim bladders at night were always distributed beneath the surface until the next morning (survival rates were 100 %). However, larvae with uninflated swim bladders at night swam upward repeatedly and later sank to the bottom of the tank (survival rates were 60 % and 38 % at 5 and 9 DAH, respectively). Larvae with uninflated swim bladders were not always able to maintain their swimming depth by swimming until the next morning. Additionally, their swimming speed and vertical swimming frequency (ratio) depended on the illumination and swim bladder conditions. Our findings show that larvae with uninflated swim bladders at night were associated with a higher risk of sinking death. The swimming energy capacity of Pacific Bluefin tuna larvae, which indicates the total amount of the energy that enables individuals to swim throughout the night without feeding, was found to be linked to sinking death.