冷、热休克法诱导黄颡鱼三倍体的比较研究

分别采用冷、热休克抑制第二极体释放的方法诱导黄颡鱼三倍体。结果表明,在卵受精后2min,5℃处理20min,胚胎时期的三倍体率达70%左右,孵化率50%左右,幼鱼时期三倍体(含嵌合体)的检出率为25%,此条件为冷休克处理的优化参数;在卵受精后2min,40℃处理2min,胚胎时期的三倍体诱导率达58%,孵化率为39%,幼鱼时期三倍体(含嵌合体)的检出率为40%,此条件为热休克处理的优化参数。正交分析得出,冷休克条件下起始休克时间是原肠期三倍化率和孵化率的重要影响因子,温度对畸形个体的产生有重要影响;热休克条件下,参考三倍体率、畸形率、孵化期相对存活率三者而言,休克温度均是重要因素。比较观察到冷休克处理组的胚胎受损情况严重,后期的成活率较热休克处理组要低,总体诱导效果逊于热休克处理组。     

热休克诱导全雌虹鳟三倍体

以虹鳟二倍体的伪雄鱼为父本（遗传型为xx），探讨了采用热休克方法阻止第二极体排放诱导全雌虹鳟三倍体的适宜条件。结果表明：虹鳟三倍体诱导率明显受处理温度、起始时间以及持续时间等因子的影响。在孵化水温为6．5℃，卵子受精后20min经26℃热处理20min，孵化率为64．62％，三倍体诱导率为86．67％；卵子受精后lOmin经26℃热处理20min，三倍体诱导率为100％，但孵化率仅为3．87％。受精卵经26℃处理的诱导效果好于24℃和28℃的（P〈0．01）。     

三种香港牡蛎三倍体幼虫诱导方法的效果比较

以卵裂率、D形幼虫发生率、三倍体率等为指标,比较了高盐、低温及咖啡因诱导香港牡蛎(Crassostrea hongkongensis)三倍体幼虫的效果,同时也分析了诱导因子强度(或浓度)、持续时间、受精卵密度及受精后开始处理时间对诱导效果的影响。结果表明,高盐诱导三倍体的最适条件组合是在卵子密度1.0×107个/L的情况下受精后15 min,用盐度40的海水持续处理10 min,此时卵裂率为(39.60±2.14)%, D形幼虫发生率为(31.46±1.06)%,三倍体率可以达到(59.53±5.90)%;低温诱导三倍体的最适条件组合是密度为2.0×10~7个/L的卵子在受精后15 min,用10℃海水持续处理10 min,此时卵裂率为(21.00±4.90)%, D形幼虫发生率为(12.68±1.21)%,三倍体率为(51.09±2.67)%;咖啡因诱导三倍体的最适条件组合是卵子密度为1.0×10~8个/L,用咖啡因终浓度2.0g/L的海水在受精后15min,持续处理20 min,卵裂率为(85.46±4.78)%, D形幼虫发生率为(71.79±3.92)%,三倍体率可以达到(56.36±2.07)%。最适诱导条件下,咖啡因的诱导效率指数0.405高于高盐处理0.187、低温处理0.065。高盐及低温处理方法诱导出的幼虫三倍体率随生长降低极快且存活率低于咖啡因诱导方法,说明3种方法中咖啡因可能更适合用于香港牡蛎三倍体幼虫的诱导。本研究为香港牡蛎三倍体育种提供了基础数据和实践经验。     

双斑东方鲀三倍体育苗生产性研究

研究了双斑东方鲀三倍体的诱导方法、技术参数的筛选及生产性育苗的模式.采用温度休克方法诱导双斑东方鲀三倍体,在水温18～20℃条件下,卵受精后5 min用40℃的水温处理双斑东方鲀受精卵10 min,三倍体诱导率100%,孵化率相对诱导量达25%;育苗采用前期室内工厂化培育与后期土池培育相结合方法,培育出全为三倍体(体长3 cm以上)苗种5.8万尾,对应孵出苗量,成活率为34.6%.     

6_二甲基氨基嘌呤诱导太平洋牡蛎三倍体_抑制受精卵第一极体释放

于 1996～ 1997年 ,用 6-二甲基氨基嘌呤 ( 6-DMAP)抑制受精卵第一极体的释放 ,诱导太平洋牡蛎产生三倍体。选用L16( 45)设计 ,进行三因素四水平的正交试验 :6-DMAP浓度 ,设15 0、30 0、45 0和 60 0μmol/L ;诱导时机 (即精卵混合后的时间 ) ,设 10、15、2 0和 2 5min ;诱导持续时间 ,设 10、15、2 0和 2 5min。试验平行重复二次。结果为最高三倍体诱导率为 ( 71.3± 1.2 ) % ,该实验组胚胎孵化率为 ( 5 5 .5± 3.1) % ,D形幼虫畸形率为 ( 10 .7± 1.6) %。根据直观分析结果 ,得出诱导太平洋牡蛎三倍体各因素的最优水平组合 :水温 2 5～ 2 5 .5℃ ,精卵混合 10min时 ,将受精卵浸泡在含 6-DMAP 60 0μmol/L的海水中 15min ;决定三倍体产生的三因素的主次顺序 :6-DMAP浓度→诱导时机→诱导持续时间。 6-DMAP浓度对三倍体诱导率影响显著 ,但诱导时机和诱导持续时间不显著。     

低渗诱导太平洋牡蛎三倍体以及与其他诱导方法的比较

通过低渗方法抑制受精卵第二极体(PB2)的释放,诱导太平洋牡蛎(Crassostrea gigas)三倍体.在水温为23～25℃的条件下,分别采用不同低渗海水(盐度分别为4、6、8、10、12、14、16),在不同处理时机,即第1个第一极体(PB1)出现、30%的PB1出现、40%的PB1出现、50%的PB1出现以及第1个第二极体(PB2)出现时,对太平洋牡蛎受精卵进行10 min、15 min、20 min、25 min持续处理.处理后,于正常盐度海水中孵化,收集D形幼虫,通过流式细胞仪进行倍性测定,确定最佳诱导条件.结果表明,当太平洋牡蛎受精卵PB1出现40%时,在盐度为8的低渗海水中,持续处理15 min,得到最高三倍体诱导率为(89.16±1.39)%.与对照组相比,低渗诱导获得的三倍体幼虫表现出明显的生长优势.将低渗方法同高温(32℃)、低温(2℃)和6-DMAP(450μmo1/L)处理等多倍体诱导方法进行比较,结果显示,低渗组的卵裂率和孵化率显著高于高温、低温和6-DMAP诱导的太平洋牡蛎三倍体(P＜0.05).6-DMAP诱导的三倍体率虽略高于低渗诱导,但差异不显著(P＞0.05).通过综合评价指数(Ie)比较,认为低渗诱导多倍体的方法比高温、低温和6-DMAP诱导具有明显的优势.     

热休克诱导黄颡鱼三倍体的研究

以正交试验设计,采用热休克法研究了诱导三倍体黄颡鱼的适宜条件.试验结果表明,在卵受精后2 min,40 ℃持续处理2 min,三倍化率可达57.5%,原肠期相对存活率43.0%,孵化期相对存活率38.5%.分析了热休克处理的参数与三倍体出现率和胚胎相对存活率的关系,诱导参数中处理温度和诱导时机为重要因素,其次为持续时间.     

低盐诱导海湾扇贝三倍体育苗技术的研究

通过低盐海水浸泡海湾扇贝受精卵抑制受精卵第二极体释放的方法诱导海湾扇贝产生三倍体。当海湾扇贝的受精卵40%出现第一极体时,立即用不同盐度梯度即22.5、20、17.5、15、12.5、10、7.5、对照组(盐度30)的海水对受精卵进行处理10、15min后,马上将处理的受精卵移入正常海水中孵化。实验结果表明,不同梯度低盐海水可以诱导海湾扇贝产生三倍体,盐度为20以上时,三倍体诱导率小于2.91%,但随着盐度的下降,三倍体诱导率迅速提高,当盐度为12.5时,三倍体诱导率高达85.91%。当盐度低于7.5时,由于D形幼虫极少,三倍体诱导率无法测出。在处理时间上,15min的处理效果比10min处理效果好。因此,本研究在低盐度条件下抑制受精卵第二极体产生海湾扇贝三倍体的最佳处理方法是低盐范围在12.5～15之间,处理时间为15min,三倍体诱导率高,孵化率也较高,适合生产上推广应用。     

红鳍东方鲀三倍体诱导的初步研究

通过冷休克的方法诱导红鳍东方鲀的受精卵,孵化后的仔鱼,用PAS-Ⅲ型细胞流速仪测定其倍性,得到较高的三倍体诱导率。受精后8 min,0℃下处理15 min和受精后5 min,2℃下处理15min三倍体率最高,为100%;受精后8 min,4℃下处理10 min倍化率最低,为20%;其余几组的三倍体率为90%。正交试验结果表明,影响三倍体诱导率的主次顺序是处理时间、处理温度、处理起始时间。     

CB与6-DMAP诱导香港牡蛎三倍体的效果比较

以三倍体率、卵裂率、D幼率、生产成本等为指标,比较了CB、6-DMAP两种化学试剂诱导香港牡蛎三倍体的效果,研究了试剂浓度、诱导时机、诱导持续时间及受精卵密度等4种因素对香港牡蛎三倍体的诱导效应。结果显示,在温度28~30°C、盐度15~25,受精卵密度为2.0×10~8个/L条件下,采用0.5 mg/L的CB在受精后15~18 min处理,诱导持续时间为20 min,可产生100%三倍体;合子的卵裂率为53.16%~63.00%,D形幼虫孵化率为47.32%~53.09%,诱导效率指数为0.47~0.53,生产成本为260元/L。相同条件下,采用浓度为75~100 mg/L的6-DMAP处理,诱导持续时间为20~25 min,受精卵处理密度4.5×10~7个/L,可产生62.52%~72.36%的三倍体;合子的卵裂率为60.00%~66.25%,D形幼虫孵化率为74.43%~90.00%,诱导效率指数为0.47~0.65,生产成本为139~185元/L。综合比较两种方法,6-DMAP诱导方法更加适合用于大规模的香港牡蛎三倍体苗种生产。本研究为香港牡蛎多倍体育种提供了研究数据与实践经验。     

Optimal conditions for cold-shock induction of triploidy in red tilapia

Production of sterile triploid red tilapia [Oreochromis mossambicus (Mozambique tilapia); Peters, 1852 × Oreochromis niloticus (Nile tilapia); Linnaeus, 1758] is an effective strategy to overcome their prolific breeding. Optimal conditions for cold-shock induction of triploidy in red tilapia were investigated by experimentally examining two variables: appropriate temperature of the shock and duration of shock treatment. A constant time after insemination of 4 min was used to determine the best combination of temperature (6, 7, 8, 9, 11, 13, 15 °C) with different durations of shock (10, 20, 30, 40, 50 min) with resultant ploidy level verified karyotypically. Shock duration for 30 min at a temperature of 9 °C was found most effective in producing maximum triploidy (98.7 %) with higher rates of hatching (63.2 %) and survival up to yolk-sac stage (75.8 %). The chromosome count confirmed that triploid percentages were higher when cold shock was used for longer durations at each temperature; however, hatching rates were generally decreased. The maximum triploid yield (82.1 %) obtained was higher than the yield obtained using heat shock (72.7 %) in red tilapia previously. The application of the results of this study has the potential to greatly improve the production of triploid red tilapia in commercial aquaculture.     

Thermal shock induction of triploidy in Atlantic cod (Gadus morhua L.)

The effects of thermal treatments on induction of triploidy in Atlantic cod have been investigated. Cold shock [−1.7±0.1°C at 20 min post fertilization (PF) for 2 h] was based on a previously developed protocol, and heat shocks, below the lethal threshold of 24°C, were at 16, 18 or 20°C applied 20, 30 or 40 min PF for 20 min. Cold shock did not affect larval survival and was ineffective for producing triploids (range 0–4%). A heat shock of 20°C at 20 min PF generated the highest percentages (range 66–100%) of triploid larvae at hatching, with survival ranging from 10% to 20% relative to the controls. Lower heat shock temperatures or delayed shocks increased survival but decreased the number of triploids, providing no net gain in triploid yield (range 1–9%). Heat shocks applied later than 20 min PF produced 2–4% tetraploid larvae at hatching. A thermal shock of 20°C initiated at 20 min PF and lasting 20 min proved to be the most generally efficient treatment for induction of triploidy in Atlantic cod.     

Induction of triploidy in the turbot (Scophthalmus maximus): II. Effects of cold shock timing and induction of triploidy in a large volume of eggs

Triploidy was induced in the turbot (Scophthalmus maximus, L.) by applying cold shocks shortly after fertilization. The combined effects of the timing of cold shock commencement after fertilization, cold shock duration and cold shock temperature were investigated. Ploidy was assessed by counting the number of nucleoli per nucleus (NOR) in larvae and also by measuring erythrocyte size in juveniles. A clear peak in triploidy induction was obtained when shocks were started between 6 and 7 min after fertilization at a pre-shock temperature of 13–14°C. With this timing, shocks of 20-min duration at 0°C gave >90% triploidy, with survival about 80% of the untreated controls. In order to ensure both high triploidy rates and high survival, it was necessary to carefully maintain the water temperature just below 0°C. Experiments with small and large volumes of eggs were performed in order to determine how changes in the relative volumes of eggs and chilled water could affect survival and triploidy induction. The best combination to induce triploidy in the turbot was as follows: shock commencement 6.5 min after fertilization, shock duration 25 min, and shock temperature between 0 and −1°C. With this combination, 100% triploidy could consistently be induced with survival 60% of the untreated control. This was successfully applied to a large volume of eggs (300 ml; 1 ml 800 eggs) in order to mass-produce triploid turbot. Triploids had lower survival rate than diploids at hatching but similar thereafter, with the ability to complete the different stages of larval rearing, indicating the viability to produce triploid turbot under farming conditions.     

Triploid induction by hyperosmotic shock in the Yesso scallop,Patinopecten yessoensis

The triploid technology is a new frontier in shellfish aquaculture and has shown encouraging results in numerous shellfish species. We induced triploid larvae in the Yesso scallop, Patinopecten yessoensis, using hyperosmotic shock for the first time in this study. Different induction parameters, including salinity strength, treatment starting point, and the duration, were tested. The highest triploid ratio of D‐shaped larvae (72.12%) was obtained by 60 ppt salinity treatment for 20 min at the first appearance of zygote showing polar body II (PB2). A significantly faster growth rate was observed during the swimming larvae stage despite a decrease in the hatching and survival ratios. The triploid ratio decreased to 46.67%, and approximately 1.76 million triploid juveniles were harvested after 90 days of cultivation. The treatment parameters can be further optimized to improve the yield of Yesso scallop triploids.     

Triploid Induction in the Yellowtail Tetra,Astyanax altiparanae,Using Temperature Shock: Tools for Conservation and Aquaculture

Triploidization is an interesting tool to produce sterile fish. In the yellowtail tetra, Astyanax altiparanae, this can be applied for aquaculture and surrogate technologies. In this study, we compared the efficacy of cold (2 C) or heat shock (38 C, 40 C, and 42 C) on triploid induction in the yellowtail tetra. The eggs were treated with cold or heat shock, 2 min postfertilization (30 min in cold shock or 2 min in heat shock). Intact embryos served as the control group. Ploidy status was confirmed by karyotyping, flow cytometry, and nuclear diameter of erythrocytes. The hatching rate decreased after cold shock (12.69 ± 15.76%) and heat shock at 42 C (0.35 ± 0.69%) in comparison with the control group (63.19 ± 16.82%). At 38 C and 40 C, hatching rates (61.29 ± 17.73% and 61.75 ± 22.1%, respectively) were not decreased. Only one triploid arose at 38 C (1/80). At 40 C, a high number of triploids arose (72/78). At 42 C, very few embryos developed into the hatching stage. A large number of haploid individuals arose after cold shock (61/75), with only one triploid. Our results indicate that heat shocking of embryos at 40 C is optimum for triploid production in the yellowtail tetra.     

Triploid Induction of Green Tiger Shrimp,Penaeus semisulcatus (De Haan, 1844) Using Temperature and Chemical Shock

Triploidy in fertilized eggs of Penaeus semisulcatus was induced by temperature and chemical shocks. The eggs, which were obtained from the shrimp broodstock maintained at 29 C, were exposed to cold temperature (8, 10, 12, and 14 C) and 6‐dimetiloaminopurine (6‐DMAP) concentrations (100, 150, 200, and 250 μM) for different durations (4, 6, and 8 min) 9 min after spawning was detected. While the highest triploidy rate of 49.7 ± 4.5% was obtained with a 200 μM 6‐DMAP concentration for a duration of 8 min, the best mean triploidy rate of 45.5 ± 2.8% for cold shock was obtained at a temperature of 10 C for a duration of 8 min. Temperature and 6‐DMAP concentration did not have significant effect on triploidy rate (P > 0.05) but shock duration had significant effect on triploidy rate for individual cold temperature shock or 6‐DMAP chemical shock (P < 0.05). Although longer durations of shock agent increased the rates of triploid induction, they generally had an adverse effect on hatching rates in the study.     

Triploidy induction in Australian greenlip abalone Haliotis laevigata (Donovan) with cytochalasin B

Triploid induction in Australian greenlip abalone, Haliotis laevigata (Donovan), was conducted by blocking the formation of the second polar body using cytochalasin B (CB). Twenty minutes after fertilization, the zygotes of greenlip abalone were treated with four CB concentrations (0, 0.25, 0.5 and 0.75 mg L⁻¹) for 10, 15 and 20 min. The ploidy of resultant larvae was determined using flow cytometry at 72-h post fertilization. Our study showed that fertilization, hatching, survival and induced triploidy of abalone larvae were significantly affected by the CB concentration and treatment duration. The effective range of CB concentration for triploid induction on greenlip abalone was 0.5–0.75 mg L⁻¹ with an induction duration of 10–15 min. The results indicate that the most effective treatment combination for triploid induction in greenlip abalone is 0.5 mg CB L⁻¹ for 15 min starting at 20-min post fertilization.     

Experimental production of triploid brown trout, Salmo trutta L., using heat shock

Abstract. This study was designed to investigate the potential of heat shock to produce triploidy in brown trout, Salmo trutta L., and to develop a methodof routinely identifying triploids in this species. Triploids were produced in all heat-shocked batches and were identified by the size of their erythrocyte nucleus, which had a volume ratio of 1:1-57 relative to diploid controls. Cytogenetic and flow cytometric analyses confirmed that trout with the larger nuclei were triploid. Heat shock of 28°Cof 10 min duration initiated 5-15 min post-insemination produced high rates of triploidy in experimental batches (88-2-100%), later shocks at 20-25 min producing lower rates (down to 60%). Reproducibilicy of tripioid rates was generally good, a maximum difference between replicates of 21.9% being observed, the majority of differences being considerably less. The highest triploid yield was produced with a heat shock of 28°C for 10 min initiated at 10 or 20 min post-insemination, the difference between replicates being due to variability in survival to hatch. Survival to hatch was generally lower in groups having higher rates of tripioidy.     

Induction of triploidy in Melicertus kerathurus (Forskal, 1775) with temperature shock

Triploidy in fertilized eggs of Melicertus kerathurus was induced by cold (8, 10, 12°C) and heat (34, 36, 38°C) shock for different duration times (2, 4 and 8 min) after 10 min of post spawning. The best individual treatment produced 64.5% triploid nauplii in cold shock application at a temperature of 10°C for a duration of 8 min. Temperature did not have significant effect (P > 0.05) on triploid rate but duration time had a significant effect (P < 0.05) for individual cold or heat shock. This study demonstrates that because of a wide variety of effective parameters, it is essential to optimize shock conditions for each species strain at each location.