繁殖期日本海螂的壳尺寸性状对重量性状的通径分析

徐筱琰; 杜美荣; 王庭豪; 蒋增杰

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繁殖期日本海螂的壳尺寸性状对重量性状的通径分析
徐筱琰^1,2, 杜美荣^1,2, 王庭豪^1,3, 蒋增杰^1,4
1.海水养殖生物育种与可持续产出全国重点实验室农业农村部海洋渔业与可持续发展重点实验室中国水产科学研究院黄海水产研究所山东青岛 266071;2.青岛海洋科技中心海洋渔业科学与食物产出过程功能实验室山东青岛 266237;3.青岛海洋科技中心海洋渔业科学与食物产出过程功能实验室山东青岛 266238;4.青岛海洋科技中心海洋渔业科学与食物产出过程功能实验室山东青岛 266239

摘要:

为了揭示繁殖期日本海螂(Mya japonica)壳尺寸性状和重量性状之间的关系，通过直观可见性状判断非直观性状，在苗种繁育中指导种贝挑选，本研究测定了185只来自青岛胶州湾繁殖期日本海螂的壳尺寸性状[壳长(X1)，壳宽(X2)，壳高(X3)]和重量性状[总湿重(Y1)，软体湿重(Y2)，性腺湿重(Y3)]，开展了壳尺寸性状对重量性状的通径分析。结果显示，繁殖期日本海螂的6个性状之间的相关系数均达到极显著水平(P<0.01)，相关性系数为0.891~0.966。壳宽对总湿重、软体湿重和性腺湿重的直接效应最大，其值分别为0.462、0.519和0.537。单一性状中，壳宽对总湿重、软体湿重和性腺湿重的影响最大，其值分别为21.34%、26.94%和28.84%。壳宽和壳高对总湿重、软体湿重和性腺湿重的共同决定程度最大，其值分别为32.88%、24.93%和21.34%。利用多元回归分析法，建立壳尺寸性状对重量性状的最优回归方程：Y1=0.295X1+1.73X2+1.128X3–72.554，R2=0.954；Y2=0.117X1+0.56X2+0.219X3–19.240，R2=0.927；Y3=0.055X1+0.362X2+0.082X3–9.402，R2=0.891。研究表明，在日本海螂苗种繁育中的种贝挑选阶段，以重量性状(总湿重、软体湿重和性腺湿重)为首要育种目标时，可以通过壳宽进行间接选择，同时考虑壳高的协同作用。研究结果可为日本海螂的选择育种工作中的种贝选择提供理论依据。

关键词: 日本海螂壳尺寸性状重量性状通径分析

DOI：10.19663/j.issn2095-9869.20240119001

分类号:

基金项目:国家自然科学基金青年基金(32202962)、中国水产科学研究院黄海水产研究所基本科研业务费(20603022024007)和国家贝类产业技术体系(CARS-49)共同资

Path analysis of morphological traits on weight traits of breeding Mya japonica

XU Xiaoyan,DU Meirong,WANG Tinghao,JIANG Zengjie

1.State Key Laboratory of Mariculture Biobreeding and Sustainable Goods, Key Laboratory of Marine Fisheries and Sustainable Development, Ministry of Agriculture and Rural Affairs, Yellow Sea Fisheries Research Institute, Chinese Academy of Fishery Sciences, Qingdao 266071, China;2.Laboratory for Marine Fisheries Science and Food Production Processes, Qingdao Marine Science and Technology Center, Qingdao 266237, China

Abstract:

In shellfish farms, to guide selection, it is important to rapidly determine the gonadal condition of the parents based on the appearance and morphology of the shells. For the intuitive shell size traits of shellfish, without the intuitive weight traits of the soft body and gonadal wet weights, the shellfish must be dissected and weighed pre-data collection in the laborious shellfish death after dissection is a significant loss to the breeding plant. It is crucial to determine weight trait growth (gonadal wet, soft body wet, and total wet weights) by measuring visual data (shell length, width, and height). Pathway analysis, which was developed by the quantitative geneticist Wright in the 1920s, identifies the correlations between parameters and categorizes their correlation coefficients into direct and indirect influences through other parameters to create the optimal regression equations. Pathway analysis to guide selective breeding of aquatic organisms was achieved for many species using the morphological traits of body mass and soft weight; however, pathway analysis of soft body and gonad wet weights, which are not readily available, was not reported. Mya japonica has a flavor comparable to that of a Crassostrea gigas whose soft body wet weight is heavier than that of an oyster of the same size, with a high meat yield and economic value. The relationship between shell size and weight traits of M. japonica during the breeding period was explored to guide seed shell selection during breeding. In this study, the shell size traits (shell length X1, width X2, and height X3) and weight traits (total wet weight Y1, soft wet weight Y2, and gonad wet weight Y3) of 185 M. japonica from Jiaozhou Bay, Qingdao, were measured, and a path analysis of shell size traits on weight traits was conducted. The results demonstrated that the correlation coefficients of six traits of the six breeding M. japonica traits reached a highly significant level (0.01), with correlation coefficients ranging from 0.891 to 0.966. The direct effects of shell width on the total, soft, and gonad wet weights were 0.462, 0.519, and 0.537, respectively. The influence of the shell width on the total, soft, and gonadal wet weights was the greatest, with values of 21.34%, 26.94%, and 28.84%, respectively. Shell width and height had the greatest degree of co-determination for total, soft, and gonadal wet weights, with values of 32.88%, 24.93%, and 21.34%, respectively. Using the multiple regression analysis method, the optimal regression equation of shell size trait to weight trait was established as Y1=0.295X1+ 1.73X2+1.128X3–72.554, R2=0.954; Y2=0.117X1+0.56X2+0.219X3–19.240, R2=0.927; Y3=0.055X1+ 0.362X2+0.082X3–9.402, R2=0.891. The results demonstrated that when weight were the primary breeding targets, indirect selection could be performed using shell width, and the synergistic effect of shell height could be considered. Our findings provide a theoretical basis for brood selection for breeding M. japonica.

Key words: Mya japonica Shell size traits Weight traits Path analysis