熊本牡蛎多嵴和无嵴品系F3生长性状的连续选择效应

为进一步检测熊本牡蛎(Crassostrea sikamea)多嵴和无嵴品系F3的连续选择反应,以2个品系F2上选组为材料,开展2个品系F3混合上选研究,评估2个品系F3生长性状的选择反应、现实遗传力及遗传改进量,解析选育过程中选择效应、品系效应及二者交互作用对生产性状的影响。结果表明:多嵴品系F3生长性状具有较高的现实遗传力,表现出较好的遗传改良效果;无嵴品系F3表现出中等现实遗传力水平,但仍具有一定程度的遗传改良潜能。养成期360日龄时,多嵴品系子代壳高、鲜重的选择反应分别为0.70、0.76;现实遗传力分别为0.40、0.43;遗传改进量分别为7.02%、12.29%;无嵴品系的选择反应分别为0.36、0.33;现实遗传力分别为0.20、0.19;遗传改进量分别为3.74%、5.72%。经过双因子分析模型检测发现:品系来源是影响F3生长性状的主要因子,选择效应是次要因子,二者间不存在明显的交互作用。由此可见,随着连续选择的进行,选择反应逐渐降低,品系来源作用增强,本研究为熊本牡蛎遗传改良和新品系培育奠定了基础。     

熊本牡蛎无嵴和多嵴品系生产性状比较

为了评估熊本牡蛎左壳放射嵴有无对其生产性能的影响,于2013年5月,以熊本牡蛎湛江群体子一代作为基础群体,筛选出无嵴及多嵴品系,采用繁殖生物学方法,比较了两个品系的表型性状差异。结果显示,野生群体中,多嵴亲本规格略大于无嵴亲本,鲜重、壳重及怀卵量均显著大于无嵴亲本;两个品系的受精孵化参数、D型幼虫大小及变态规格彼此间无显著差异;多嵴品系存活力及生长潜力在幼虫及养成期间显著高于无嵴品系。中间育成期间,湛江及大风江牡蛎养殖区环境对两品系生长性状造成了一定程度影响,表现出明显的环境效应,但是对存活力尚未造成影响。熊本牡蛎左壳放射嵴无相对于有是显性性状,主要受到一对显性基因控制,而多嵴性状是隐性性状,可以稳定遗传。研究为熊本牡蛎多嵴品系培育及其左壳放射嵴遗传机制奠定了坚实的理论基础与实践经验。     

深凹壳型香港牡蛎选育群体生长性状的遗传参数估计

为了培育壳型和生长性状优良的深凹壳型香港牡蛎新品系,以广东台山镇海湾野生香港牡蛎天然采苗的2龄养殖群体为基础群体,以壳型指数D为指标,按照10%留种率和1.755选择强度,利用截头法进行深凹壳型香港牡蛎的群体选育;分析了幼虫期、中间培养期、养成后期的选择反应、遗传获得和现实遗传力等遗传参数。结果发现,选择组的壳高和壳型指数D均大于对照组,遗传参数估算值随着个体的增大而增加。幼虫期,壳高的平均选择反应、平均遗传获得、平均现实遗传力分别为0.363±0.167、1.678%±0.416%、0.207±0.095,中间培养期分别0.639±0.115、7.618%±2.666%、0.364±0.065,养成后期分别为0.668±0.179、8.861%±3.072%、0.381±0.102。养成后期,壳型指数D的平均选择反应、平均遗传获得、平均现实遗传力分别为0.748±0.066、9.090%±0.565%、0.426±0.038。研究结果为培育深凹壳型、生长性能良好的香港牡蛎优良品种提供了实验依据和理论基础。     

长牡蛎壳金选育群体生长性状的选择效应

长牡蛎是一种世界性的养殖贝类,同时是我国最重要的经济贝类之一,壳色美观和快速生长是目前长牡蛎遗传育种的2个重要目标。2010年通过长牡蛎壳色性状的家系选育,获得了壳白、壳黑、壳金和壳紫4种壳色品系。实验以第二代壳金品系为基础群体,对长牡蛎壳金群体的生长性状进行定向选育,分析了长牡蛎壳金选育群体壳高性状的选择反应、遗传获得和现实遗传力。结果显示,养成阶段选择组的壳高均大于对照组,350日龄后表现出显著的生长优势;幼虫期,壳高性状的平均选择反应、遗传获得和现实遗传力分别为0.549±0.277、3.717%±2.611%和0.339±0.171,养成期分别为0.436±0.138、8.253%±1.014%和0.270±0.086。选择组的贝壳金黄色和外套膜金黄色比例分别提高了22%和10%。研究结果为长牡蛎壳金优良品系培育提供了重要基础资料。     

长牡蛎壳金性状遗传参数评估及与生长性状的关联分析

采用家系选育与群体选育相结合的方法,以壳金性状和生长性状为主要选育指标,经过连续4代的选育获得了长牡蛎第4代壳金选育品系(F4)。本实验以F4代为亲本,采用巢式设计方法和人工授精技术,成功构建了25个长牡蛎壳金全同胞家系,分别测定了每个家系生长到9月龄时30个个体壳金性状颜色参数和生长性状,分析了2类性状的表型变异,并对壳金性状的遗传参数及与生长性状的相关性进行了分析。结果显示,壳金性状颜色参数L*、a*、b*、ΔE的遗传力分别为0.13±0.09、0.69±0.19、0.30±0.13、0.38±0.15;L*、a*、b*和ΔE之间的遗传相关和表型相关范围分别为–0.25~0.37、–0.1 9~0.8 0;颜色参数与各生长性状的遗传相关和表型相关均较低,分别为–0.04~0.26、–0.10~0.13。本研究表明长牡蛎壳金性状颜色参数的遗传力多为中高等水平,对其颜色继续进行选择改良,预期能达到良好的效果。此外,壳金性状与生长性状的相关性较低,不能利用二者之间的关系进行相互选择,只能将壳金性状和生长性状均作为目标性状进行协同选择,以实现同步改良2个性状的目的。     

壳紫长牡蛎家系生长存活比较及生长性状的遗传参数评估

为了培育壳色和生长性状优良的壳紫长牡蛎(Crassostreagigas)新品系,2021年通过家系选育的方式,以壳色性状为主要选育指标,建立了第1代壳紫长牡蛎选育群体。本研究以壳紫F1为亲本,采用平衡巢式设计建立了36个全同胞家系,并以野生长牡蛎为亲本建立对照组,比较分析了各家系在生长和存活方面的性能表现;同时利用多性状动物模型对壳紫家系幼虫和稚贝期的生长性状遗传参数进行了评估。结果显示,不同生长阶段壳紫长牡蛎家系的存活率和壳高均值均高于对照组,幼虫期分别提高了1.49%～10.18%和3.75%～15.94%,稚贝期分别提高了4.05%～16.94%和15.95%～18.25%。不同壳紫家系的生长和存活情况也存在差异,没有发现在存活率和生长性状方面同时具有优势的家系。壳紫长牡蛎幼虫期壳高和壳长的狭义遗传力范围分别为0.43～0.84和0.49～0.80,稚贝期壳高和壳长的遗传力分别为0.15～0.33和0.18～0.37,均属于中高等遗传力。不同生长阶段壳紫长牡蛎家系壳高和壳长的遗传相关与表型相关均为正相关,幼虫期的相关系数分别为0.67～0.97和0.17～0.51,稚贝期为0....     

壳白长牡蛎品系生长和壳色性状遗传参数估计

以经过连续4代家系选育获得的壳白长牡蛎(Crassostrea gigas)选育系为亲本,通过巢氏平衡设计建立了30个全同胞家系混合养殖,采用微卫星多重PCR技术进行家系鉴定,基于REML法估算24月龄壳白长牡蛎的生长性状和壳色性状的遗传参数。结果表明,壳白长牡蛎品系壳高、壳长、总重、壳重、L~*(明度)、a~*(红绿轴色品指数)和b~*(黄蓝轴色品指数)的遗传力为中高等水平,依次为0.35±0.13、0.18±0.09、0.20±0.09、0.16±0.08、0.16±0.08、0.27±0.11和0.19±0.08,壳宽、肉重、出肉率、壳型指数A和壳型指数B的遗传力为低等水平,依次是0.07±0.02、0.11±0.06、0.02±0.03、0.08±0.06和0.11±0.06。壳高、壳长、壳宽、总重、壳重和肉重之间的遗传相关和表型相关均为正相关,其中,壳高、壳宽和总重与其他生长性状的相关性较高,分别为0.40±0.65~0.90±0.14、0.39±0.55~0.97±0.24和0.50±0.66~0.99±0.02。壳型指数A和壳型指数B与壳高均为较高的负相关,分别为–0.94±0.16和–0.77±0.19,表明仅以壳高性状为选育目标时,可能不会对长牡蛎壳型改良产生作用。壳白长牡蛎壳色参数与生长性状之间的遗传相关范围为–0.09±0.42~0.91±0.74,不同性状间的遗传相关差异很大,其中L~*与生长参数遗传相关较高,为0.49±0.29~0.91±0.74,表明以壳高、壳长、总重和L~*任一个为选育目标时,其他生长性状都可以获得提高。壳色参数间L~*与a~*负的相关性最高,为–0.96±0.04,L~*与b~*和a~*与b~*相关性较低,分别为–0.08±0.36和0.21±0.31,表明以L~*为选育目标时,可间接降低a~*值。本研究为合理制定壳白长牡蛎新品系育种方案和选择反应预测提供了参考依据。     

长牡蛎壳黑和壳白选育群体生长性状的选择效应

为了培育壳色性状优良且生长性状良好的长牡蛎(Crassostrea gigas)新品系,本研究以5个壳黑第四代家系和5个壳白第四代家系的成贝为基础群体,利用截头法对壳高进行选择,构建了壳黑和壳白快速生长系第一代群体,分析了两个选育群体的壳高和活体体重的选择反应、遗传获得和现实遗传力等遗传参数。结果表明,在长牡蛎收获的490日龄,壳黑群体和壳白群体选择组壳高较对照组壳高分别提高(9.83?1.68)%和(9.97?1.87)%,体重分别提高(10.16?3.64)%和(11.36?1.96)%。两选育群体壳高的平均现实遗传力分别为(0.353?0.09)和(0.405?0.111),体重的平均现实遗传力为(0.192?0.080)和(0.244?0.123)。本研究表明壳黑群体和壳白群体具有较大的遗传方差,在对壳高生长速度直接选择的同时实现了对活体体重的间接选育,可继续通过群体选育提高生长速度。本研究结果可以为培育出壳色美观、生长性状良好的长牡蛎优良品种提供科学依据。     

长牡蛎壳橙性状遗传参数评估及与生长性状的关联性

长牡蛎壳橙快速生长品系是结合群体选育与种内群体间杂交方法，以壳色性状和生长性状为选育指标，经过连续3代选育获得的新品系。本研究以第1代长牡蛎壳橙快速生长品系(G₁)为亲本，采用巢式设计建立了48个混养家系，共获得863个个体。利用微卫星标记对混养家系进行了系谱分析，并基于REML法评估了长牡蛎壳橙快速生长品系壳色性状的遗传参数及与生长性状的相关性。结果显示，863个个体中，有851个个体被准确鉴定其所属家系；长牡蛎壳橙快速生长品系壳色性状颜色参数指标a^*(红绿轴色品指数)、b^*(黄蓝轴色品指数)和ΔE (色差)等均具中高等遗传力，大小依次为0.47±0.23、0.42±0.21和0.56±0.29。4个颜色参数指标间的遗传相关和表型相关范围分别为-0.79~0.86和-0.45~0.48。壳色性状与各生长性状的遗传相关和表型相关较低，分别为-0.33~0.17和-0.04~0.11。研究表明，在长牡蛎壳橙快速生长品系育种过程中，对壳色性状进行选育可以得到预期的改良效果。此外，壳橙性状与生长性状应分别作为目标性状进行协同选择，以实现同时改良两个性状的目的。本研究可为长牡蛎壳橙快速生长品系选育提供基础资料。     

壳白长牡蛎基因型与环境互作(G×E)效应分析

为探索壳白长牡蛎品系的壳色性状和生长性状的基因型与环境互作(G×E)效应,利用巢氏设计构建全同胞家系,每个家系分成两组分别在乳山和荣成海域进行养殖。利用线性混合模型和REML法分析11月龄壳白长牡蛎生长性状和壳色性状的遗传力及G×E效应。采用最佳线性无偏预测法(BLUP法)估计壳高和L~*两个性状的育种值,并通过加权获得综合育种值来筛选优良家系。结果显示,乳山组和荣成组的壳白长牡蛎生长和壳色性状的遗传力不同,分别为(0.14±0.08)～(0.62±0.18)和(0.01±0.03)～(0.78±0.19),可能存在尺度效应。以不同环境为固定效应,综合两个环境计算出的生长和壳色性状的遗传力为(0.02±0.02)～(0.51±0.09),然而由于部分全同胞家系缺失和模型不收敛的原因,估计模型中未包括母本/共同环境效应和显性效应,上述遗传力估计值偏高。本研究中生长和壳色性状在两个环境间的遗传相关为(–0.47±0.40)～(0.75±0.18),均小于0.8,表明壳白长牡蛎品系的生长和壳色性状都具有明显的重排效应,壳白长牡蛎品系其选育需要针对不同的养殖环境培育不同适应性的选育家系。综合育种值排名前20的个体其家系来源比例表明,家系G1和G21对于乳山海域表现出特殊的适应性,而家系G4、G22和G5对荣成海域环境具有特适性,家系G2则对两个环境具有普适性。研究为壳白长牡蛎品系的良种选育提供了重要的参考依据。     

Selection response and realized heritability for growth in three stocks of the Pacific oyster <Emphasis Type="Italic">Crassostrea gigas</Emphasis>

To estimate response to selection and realized heritability for shell height, a one-generation selection was performed in the Pacific oyster Crassostrea gigas using three stocks from China (stock C), Japan (stock J), and Korea (stock K). Applying about the same intensity of selection in the upward direction, three selected and three control lines were created, which were reared under the same environmental conditions at larvae, spat, and grow-out stages. Stock C and stock J showed significantly higher response to selection and realized heritability than stock K at spat and grow-out stages (P < 0.05). At harvest on day 360, the selected lines of stocks C, J, and K were 12.2, 12.2, and 7.9% larger than their control lines, respectively, for shell height. When averaged across the grow-out period, the genetic gain for stocks C, J, and K was 13.2 ± 1.2, 13.2 ± 1.0, and 7.2 ± 0.7%, respectively, and realized heritability was 0.334 ± 0.028, 0.402 ± 0.024 and 0.149 ± 0.027, respectively. The relatively high realized heritability estimate obtained for stock C and stock J indicates that there is genetic variation in the two stocks and that selective breeding by mass selection is very promising.     

Realized heritability and response to selection for shell height in the pearl oyster Pinctada fucata (Gould)

The common pearl oyster, Pinctada fucata (Gould), is the most important species that is cultured for production of marine pearls in China. Heavy mortality and the decline of pearl quality have resulted in a breeding programme being established in recent years. In this study, we conducted selective breeding for the second generation of pearl oyster P. fucata (JCS-2) by mass selection for shell height (SH) with a selection intensity of 1.614, and analysed the growth of the selected line (JCS-2) and the non-selected control line (JCC) during a 1-year grow-out period. The results show that the selected line grew faster than the control one in the SH and total weight (TW) ( P <0.05), and there were higher proportion of larger sized oysters. Coefficient of variation for SH of JCS-2 was smaller than that of JCC. The current genetic gains and realized heritability for JCS-2 averaged 16.03 ± 4.79% and 0.713 ± 0.208 at 3–15 months of age respectively. The findings indicated the selection response to faster growth for SH is markedly effective in the second generation, and there was a high correlated response of TW when selecting for SH.     

缢蛏选育系F5的生长优势比较及育种效应分析

以6个缢蛏(Sinonovacula constricta)自然群体(浙江象山群体、浙江乐清群体、福建霞浦群体、福建长乐群体、江苏射阳群体和上海崇明群体)为材料,构建基础群体F_0,采用群体选育方法进行多代连续选育(选择强度2.063),比较了选育系F_5与对照群体的生长差异,并估计F_5的选择反应、现实遗传力和遗传获得。结果表明,F_5的卵径及受精率与对照组无显著差异(P0.05),但F_5的变态率、存活率及后期壳长生长明显优于对照组(P0.05);7~360日龄F_5壳长的选择反应、现实遗传力与遗传获得的变化范围分别为0.30~0.78,0.14~0.37和4.83%~42.18%,平均为(0.49±0.06),(0.23±0.08)和(26.49±11.73)%。研究结果表明,对缢蛏的连续多代选育是有效的,可以明显提高其存活能力和主要经济性状。     

凡纳滨对虾生长与高氨氮耐受性的遗传力及选择反应研究

基于选择指数法对凡纳滨对虾(Litopenaeus vannamei)生长和高氨氮耐受性进行选择,用3种方法评估选择效果:Ⅰ)比较选择系和对照系相关性状的育种值;Ⅱ)比较选择家系和对照家系的最小二乘均值;Ⅲ)比较选择系与对照系表型值,计算相关性状的现实遗传力、遗传获得,并采用BLUP法估算相关性状的遗传力及遗传相关。结果显示,生长性状的选择反应为0.493~1.039,高氨氮耐受存活的选择反应为0.028~0.046;凡纳滨对虾生长性状的现实遗传力为0.288~0.315,遗传获得为6.45%~20.16%,高氨氮耐受成活率的现实遗传力为0.016,遗传获得为2.09%;BLUP法估算生长性状遗传力为0.216~0.284,且显著(P0.05),高氨氮耐受性遗传力为0.028±0.026,生长性状间呈高度遗传正相关为0.871~0.948,体质量与高氨氮耐受性间的正遗传相关为0.180±0.032,且显著(P0.05)。研究表明,采用选择指数法选育一代后,生长性状提高明显,高氨氮耐受性提高较小;选育群体生长性状具有较大遗传改良潜力,如何快速提高选育群体的高氨氮耐受性有待进一步研究。     

Genetic parameters of growth and survival in the Pacific oyster Crassostrea gigas

The Pacific oyster Crassostrea gigas is a representative bivalve mollusc that is widely cultured in the world and is the largest molluscan group cultured in China. In order to assess the feasibility of improving survival of C. gigas through genetic selection, the heritability and genetic correlations for growth and survival traits between different life stages were examined. Genetic parameters were estimated based on intraclass correlations of 49 full‐sib families (29 half‐sib families) in larvae (4 and 20 days after fertilization) and spat (140 days after fertilization) stages. The heritability for growth traits in larvae and spat was 0.30–0.86 and 0.53–0.59, respectively, and varied with ages. The heritability of survival was low in larvae (0.13 ± 0.05 and 0.17 ± 0.04, respectively for 4 and 20 days after fertilization) but medium (0.39 ± 0.07) in spat, suggesting that selection for increasing spat survival was feasible. The genetic correlation between growth traits within age was medium to high and positive (ranging from 0.47 to 0.96, respectively, between shell length (SL) and shell height (SH) at 20 days and between SL and SH at 140 days after fertilization), suggesting that selection to improve single growth trait will cause positive response in another growth traits in C. gigas. The genetic correlations between survival and growth traits at 140 days were low but positive (ranging from 0.23 to 0.27, respectively, between survival and SH and between survival and SL at 140 days after fertilization), suggesting that selection for survival may not have a negative response in growth. Overall, this study suggests that survival traits should be taken as improving target of next selection breeding programme in C. gigas.     

Divergent selection for shell length in two stocks of small abalone Haliotis diversicolor

To determine whether genetic improvement can be attained through a selective breeding programme, divergent selection for shell length was applied to two stocks of Haliotis diversicolor. Stock A was descended from the cross between males from a Japanese wild population and females from a Taiwan aquacultured population and Stock B was from the Taiwan cultured population, which had been successively cultured in mainland China for about 10 generations. The 10% largest and 10% smallest abalones for each of these two stocks were selected as parents for the large‐selected and small‐selected lines respectively. Equal numbers of abalone were randomly chosen from the two stocks to serve as parents for the control lines before the selection. The selected and control lines were reared under the same conditions at early juvenile, later juvenile and grow‐out stages. Stock A showed a significantly higher response to selection and realized heritability than Stock B (P<0.01). The large‐selected line of Stock A and Stock B grew 12.79% and 4.58% faster than their control lines on shell length respectively. The average realized heritability for shell length was 0.441±0.064 for Stock A and 0.113±0.013 for Stock B. Responses to selection were different at different ages in each stock and the body weights of the selected lines were significantly different from the control lines in both stocks at the grow‐out stage. Asymmetric responses to selection in the two directions were also observed in both stocks. Differences in response to selection and realized heritability between the two stocks are presumably due to genetic variability.     

长牡蛎第三代选育群体生长性状的选择效应

为了培育长牡蛎的高产抗逆新品种,实验采用群体选育方法构建了中国、日本和韩国3个种群的快速生长选育系,2007年至今已连续进行了6代选育。本实验对长 牡蛎选育F₃代壳高和活体体质量的增长、选择反应和遗传获得等遗传参数进行了分析。结果表明,从第120日龄开始,中国、日本和韩国3个选育群体的壳高和 活体体质量均显著高于对照组,在420日龄时,平均壳高较对照组分别高13.4%、10.1%和10.5%,平均活体体质量较对照组分别重18.5%、13.4%和11.6%;壳高的平均现实遗传力分别为0.447±0.226、0.471±0.297和0.367±0.167,表明适于对壳高的生长速度进行进一步的选育。长牡蛎中国、日本和韩国选育F3代活体 体质量的遗传获得平均值分别为16.01%±3.82%、15.03%±5.21%和11.57%±5.15%,表明对长牡蛎壳高的生长速度进行选育时,活体体质量的生长速度也得到了明显提高。本研究结果可以为长牡蛎快速生长品系的连续选育提供依据。