基于陆基工厂化养殖模式下的大黄鱼生长潜力评估及缩代快繁

Assessment of growth potential and accelerated generation turnover of Larimichthys crocea under a land-based industrial aquaculture system

  • 摘要:
    目的 探究大黄鱼在陆基工厂化养殖模式下的可行性,挖掘该模式下大黄鱼的生长潜力,并促进其性成熟进程,为工厂化养殖模式在大黄鱼育种中的应用提供依据。
    方法 在陆基工厂化养殖条件下,对1 842尾6月龄大黄鱼注射被动集成应答器(PIT)标签,开展为期6个月的养殖实验,每月测定个体生长性状表型数据。评估群体生长特征,筛选高生长潜力个体。选取35尾14月龄个体,经短期营养强化后,注射促性腺激素A3进行人工催产,完成陆基工厂化全周期养殖。
    结果 随着月龄增加,大黄鱼群体日增重越来越大,但生长速率受水温和遗传影响呈现波动变化,且个体间生长性能差异逐渐增加,具体表现为:基于个体生长轨迹的聚类分析,可将群体分为4类生长类型,其中类型1和类型4在生长速率上存在显著差异;通过构建基于主成分分析的综合生长潜力评价模型,可以有效区分高、低生长潜力个体,该结果与生长轨迹聚类分析结果一致。工厂化养殖模式下,大黄鱼群体14月龄可以达到性成熟并成功繁育出25万尾鱼苗。
    结论 陆基工厂化养殖模式可支撑大黄鱼实现稳定生长并显著加快性成熟进程,14月龄即可完成繁育,显著缩短了世代周期。该模式在挖掘生长潜力、提高育种效率及推动大黄鱼种业发展方面具有较高的应用价值。本研究为大黄鱼陆基全周期工厂化养殖模式的建立提供了实践依据,并为生长性状精准评价及高生长潜力种质筛选奠定了基础。

     

    Abstract: The Larimichthys crocea is a key species in China's marine aquaculture industry. However, production is currently dependent on nearshore cage farming, which is susceptible to environmental fluctuations, disease outbreaks and extreme weather. This leads to unstable growth and inconsistent individual performance. In contrast, land-based factory farming systems enable precise control of environmental conditions, improved biosecurity and continuous monitoring of fish growth and health. This makes them a promising alternative for stable production and selective breeding. The aim of this study was threefold: to evaluate the feasibility of land-based factory farming for L. crocea; to investigate its growth performance under controlled conditions; and to assess its potential to accelerate sexual maturation for breeding applications. A total of 1,842 six-month-old fish were tagged with passive integrated transponder (PIT) tags and reared for a further six months in a land-based factory farming system. Individual growth traits were measured monthly to monitor dynamic growth patterns. Growth trajectory clustering was employed to identify distinct growth types, and a principal component analysis (PCA) model incorporating final body weight, average daily weight gain and growth stability was developed to provide a comprehensive evaluation of growth potential. Furthermore, 35 individuals aged 14 months were selected for nutritional enhancement and induced spawning using gonadotropin A3. The population showed a steady increase in body weight over time. However, growth stability decreased and inter-individual variation increased during the culture period. Average daily weight gain initially declined, before increasing at later stages. Although initial body weights were similar, divergence in growth became increasingly pronounced over time, indicating significant heterogeneity in growth potential. Four distinct growth trajectories were identified, demonstrating significant variations in final body weight and growth rate. Only a small proportion of individuals maintained consistently high growth performance. PCA-based evaluation effectively distinguished between individuals with high and low growth potential, which was consistent with the clustering results. At 14 months of age, the population reached sexual maturity and produced approximately 250,000 larvae. Land-based factory farming can support stable growth of L. crocea and significantly accelerate sexual maturation, enabling reproduction at 14 months and effectively shortening the generation cycle. This study provides evidence for establishing a full-cycle land-based farming system for L. crocea, and offers a framework for evaluating growth traits and identifying superior germplasm resources, supporting modern selective breeding and intensive aquaculture development.

     

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