饥饿和再投喂对青蛤(Cyclina sinensis)幼虫生长、存活及变态的影响

在温度18.2～20.6℃,盐度23～25,pH 7.96～8.14 的条件下,研究了饥饿和再投喂对青蛤幼虫生长、存活及变态的影响.结果表明:在饥饿状态下,幼虫具有生长现象,且随着饥饿时间的延长,壳长逐渐接近一个常值而不再生长;幼虫可以由面盘幼虫发育到足面盘幼虫.随饥饿时间延长存活率下降;且足面盘幼虫及其变态规格、单水管稚贝规格随着饥饿时间延长而减小;幼虫的不可逆点(PNR)为12.48d;延迟变态时间长达12.7d.饥饿后再投喂相同的时间,幼虫能够恢复生长,存活的幼虫能够变态;稚贝表现出补偿生长现象,以壳长作为衡量标准,完全补偿生长能力依次为:S10＞S11＞S12＞S1＞S2＞S3;超补偿生长能力依次为:S9＞S8＞S7＞S6＞S5＞S4.     

哲罗鱼稚鱼最佳投喂策略

为探讨哲罗鱼稚鱼的最佳投喂策略,设置了饥饿再投喂试验、饥饿再投喂恢复试验以及日投喂频率试验.结果表明: 饥饿再投喂试验中,各饥饿组未表现出补偿生长现象.但在饥饿再投喂恢复试验中,各饥饿组表现出不同程度的补偿生长,其中S_1/2组(饥饿1/2 d投喂1/2 d)体质量的增加量与对照组接近,表现出完全补偿生长.表明在哲罗鱼早期稚鱼阶段(体质量0～2 g,水温9～15.3 ℃),S_1/2是可以考虑使用的投喂方法.日投喂频率试验中,T₃组(日投喂3次)体长、体质量的增加量以及特定生长率均最高,饵料转化率也相对较高.表明在哲罗鱼后期稚鱼阶段(体质量2～21 g,水温8.8～15.5 ℃),以日投喂3次为宜.     

哲罗鱼稚鱼最佳投喂策略

为探讨哲罗鱼稚鱼的最佳投喂策略,设置了饥饿再投喂试验、饥饿再投喂恢复试验以及日投喂频率试验.结果表明: 饥饿再投喂试验中,各饥饿组未表现出补偿生长现象.但在饥饿再投喂恢复试验中,各饥饿组表现出不同程度的补偿生长,其中S_1/2组(饥饿1/2 d投喂1/2 d)体质量的增加量与对照组接近,表现出完全补偿生长.表明在哲罗鱼早期稚鱼阶段(体质量0～2 g,水温9～15.3 ℃),S_1/2是可以考虑使用的投喂方法.日投喂频率试验中,T₃组(日投喂3次)体长、体质量的增加量以及特定生长率均最高,饵料转化率也相对较高.表明在哲罗鱼后期稚鱼阶段(体质量2～21 g,水温8.8～15.5 ℃),以日投喂3次为宜.     

不同饵料和饥饿对魁蚶幼虫生长和存活的影响

在水温23.2-24.0℃,盐度29.5-30.0条件下,研究了5种单胞藻饵料和饥饿对魁蚶浮游幼虫生长与存活的影响.投喂不同饵料试验中,球等鞭金藻与4种单胞藻混合投喂试验组幼虫的特定生长率、眼点幼虫比例和壳长均显著高于单一投喂试验组,其中球等鞭金藻与小球藻混合投喂的效果最好;投喂单一饵料试验中,球等鞭金藻组幼虫的生长、眼点幼虫比例与存活率显著高于其它试验组.在饥饿试验中,不同饥饿天数条件下幼虫的存活率差异不显著;生长方面,饥饿1-2d较短时间与一直投喂对照组的幼虫相比较,特定生长率、眼点幼虫比例、壳长的差异不显著,但随着饥饿时间延长,幼虫的生长变慢且眼点幼虫比例下降,一直饥饿情况下幼虫的生长基本停滞.研究结果可以为魁蚶人工苗种繁育技术的改进提供参考依据.     

饥饿对银鲫血液组分和卵巢发育的影响

对银鲫 (Carassiusauratusgibelio)进行投喂、饥饿 (1～ 4周 )、饥饿投喂 (饥饿 2周再投喂 2周 )处理后 ,测定其血液组分和卵巢发育的指标。结果表明 :饥饿处理后银鲫血液中血糖、甘油三酯的含量显著降低 ;红细胞数量、血红蛋白含量和胆固醇含量先显著降低 ,随后回升到投喂组水平 ;在饥饿过程中白细胞的数量、红细胞的长短径、红细胞沉降率和总蛋白均无明显变化。饥饿投喂处理的银鲫血液中红细胞数量、甘油三酯和胆固醇含量与投喂组无差异 ,但血糖含量仍显著低于投喂组 ,而白细胞数和血红蛋白含量显著高于投喂组。饥饿 4周延缓了银鲫卵巢发育 ,其性腺成熟系数和卵径均显著低于投喂组 ;饥饿投喂组的性腺成熟系数和卵径仍显著低于投喂组。分析说明饥饿阻碍了银鲫的卵巢发育 ,而饥饿对银鲫血液组分的影响在再投喂后得到恢复。     

淡水养殖太平洋鲑循环饥饿后补偿性生长效果研究

用16.1%脂肪,38.1%蛋白质含量日粮饲养108尾初始重约为240g的太平洋鲑(Oncorhynchusspp.)于0.25m3的水族箱中64d,水温为15.5±3.7℃。实验分6组,分别为对照组(每天投喂),实验1组(隔天投喂),实验2组(隔2天投喂2天),实验3组(隔4天投喂4天),实验4组(隔8天投喂8天),实验5组(隔16天投喂16天)。每组设3个平行水族箱,每箱6尾鱼。研究淡水养殖太平洋鲑多重周期饥饿后补偿性生长效果。实验结果表明:(1)各试验组太平洋鲑成活率均为100%。实验1、2、3组太平洋鲑鱼体增重接近对照组,其恢复摄食期间特定生长率、摄食率、食物转化率均显著或极显著高于对照组(P<0.05或0.01)。而实验4、5组鱼恢复摄食期间虽摄食率极显著高于对照组(P<0.01),但其鱼体增重、特定生长率、食物转化率均极显著低于对照组(P<0.01);(2)实验各组鱼肥满度、肝体比、肝脏脂肪和糖原含量、肌肉中脂肪含量较对照组均有不同程度下降,肝脏脂肪中总饱和脂肪酸比例上升,而总多不饱和脂肪酸比例下降;(3)实验1、2、3组血浆中甘油三酯、胆固醇和低密度脂蛋白显著低于对照组,而葡萄糖、血清中甲状腺激素T4浓度显著高于对照组(P<0.05)。实验结果表明,初重约240g太平洋鲑饥饿1—4d,再循环投喂相同时间64d后,获得了接近完全补偿生长效果,表现为其恢复摄食期间摄食率和食物转化率明显上升,生长速率明显加快,饲料报酬明显提高,鱼体增重接近持续喂食的对照组,养殖效益明显提高。但饥饿8—16d再循环投喂相同时间后,表现为无补偿生长效应,食物转化率和生长速率明显下降,鱼体增重极显著低于持续喂鱼的对照组。     

饥饿及再投喂对日本囊对虾糖代谢的影响

研究了日本囊对虾在饥饿和再投喂下血糖、肝胰脏糖原和肌糖原含量的变化.结果表明：在饥饿状态下,日本囊对虾肝胰脏糖原含量和血糖浓度在饥饿开始时迅速下降,肌糖原含量在饥饿10 d时下降到最低值,在饥饿10~15 d时通过糖原异生作用又恢复至最初水平,但随着饥饿时间的延长,糖原含量持续下降.恢复投喂后,肝胰脏糖原含量和肌糖原含量均能得到较好恢复,饥饿10 d和 15 d组的血糖浓度在恢复投喂10 d后显著高于对照组,但饥饿25 d组的血糖浓度始终显著低于对照.表明饥饿时间过长,对血糖浓度的恢复有较大影响     

日本沼虾继饥饿后补偿生长研究

在25.0±1℃条件下,对日本沼虾Macrobrachium nipponense (湿重, 0.52～0.64 g )进行了不同时间的饥饿处理后再供食的恢复生长实验.对照组C连续饱食投喂18 d;处理组S2、S4和S8分别饥饿2、4和8 d后再饱食投喂16、14和10 d.结果 饥饿结束时各处理组的湿重均显著低于对照组;实验结束时S2、S4组与对照组间的湿重差异不显著,而S8组的湿重仍显著低于对照组;恢复生长时各处理组的湿重摄食率、食物转化率和生长率开始显著高于对照组,但随着恢复时间延长又逐步达到对照组水平.随着饥饿时间延长,日本沼虾标准代谢率降低.在恢复投喂后又逐步回升到对照组水平.实验结果表明,日本沼虾继饥饿后再恢复喂食出现完全或部分补偿生长效应不仅是由于增加食欲,提高了摄食水平,同时也改善了食物转化率.因此,补偿生长是这两种生理因素共同作用的结果.     

上市前限喂对池塘养殖异育银鲫生长及品质的影响

实验采用5种投喂水平:饱食（R100）、80%饱食（R80）、60%饱食（R60）、40%饱食（R40）、饥饿（R0）,旨在探究上市前一个月的池塘养殖中,采用不同程度限喂的投喂策略对异育银鲫生长和品质的影响。结果表明,当投喂水平小于60%,特定生长率（SGR）显著下降,而屠宰率则表现出相反趋势。饥饿组实验鱼呈现出较瘦体形和较硬的肌肉质地。对可能影响肌肉质地的脂肪含量和胶原蛋白总量分析发现,随着投喂水平的降低肌肉脂肪含量显著减少但胶原蛋白总量无显著差异。投喂水平的降低导致鱼体各组织脂肪含量的降低,尤其是内脏脂肪的显著减少。通过SGR与脂肪含量的线性模型,SGR分别解释背肌、腹肌、内脏脂肪含量总变化的56%、66%、71%。在各投喂水平条件下肌肉的粗蛋白含量和必需氨基酸与非必需氨基酸之比维持相对稳定,表明在上市前一个月的池塘养殖中,限喂的方式并未对肌肉的蛋白营养价值造成不良影响。       

缺氧胁迫对菲律宾蛤仔(Ruditapes philippinarum)生理代谢的影响

采用苏木精-伊红(H-E)染色的方法,对菲律宾蛤仔(Ruditapes philippinarum)在缺氧(DO2 mg·L-1)胁迫20 d后组织结构进行研究,同时对菲律宾蛤仔在正常充氧(对照组)和缺氧状态下(缺氧组)的耗氧率、排氨率(NH3-N)、CO2排出率和O∶N进行研究,以期了解缺氧条件下菲律宾蛤仔生理代谢特征及其代谢变化规律。结果表明:缺氧胁迫20 d后菲律宾蛤仔组织结构与对照组相比出现差异,缺氧组个体组织中分布有零星的深紫色圆斑点,可能是由于缺氧引起菲律宾蛤仔脂质代谢发生异常,形成脂质沉积;在22℃水温条件下,随着缺氧胁迫时间的推移,缺氧胁迫对菲律宾蛤仔耗氧率、排氨率、CO2排出率影响显著;在缺氧胁迫2 d时,菲律宾蛤仔的耗氧率、排氨率和CO2排出率呈下降趋势,分别为0.566、0.079和26.236 mg·g-1·h-1,菲律宾蛤仔耗氧率和排氨率在缺氧胁迫2 d达到最低值,而CO2排出率在第20 d达到最低值,为7.422 mg·g-1·h-1,约为对照组的1/2;缺氧组的O∶N比值范围是6.25~12.11,且在缺氧20 d达到最高值,为12.11。由此可知,缺氧胁迫对菲律宾蛤仔的组织结构和生理代谢产生了影响,缺氧组的菲律宾蛤仔组织结构异常、活力下降,生理代谢功能降低,研究结果可为菲律宾蛤仔养殖的科学管理提供依据。     

Effects of starvation on growth, survival, and body biochemical composition among different sizes of Manila clam Ruditapes philippinarum

A study was conducted to investigate the impact of starvation on different sizes of Manila clam Ruditapes philippinarum (0.66 ± 0.11, 2.12 ± 0.38, and 11.65 ± 0.84 mm in shell length, respectively) in the summer of 2008. Different size clams were starved for 7, 15, 30, 45, and 60 d, respectively, and followed by refeeding for 30 d. During the study, the water temperature ranged 26.2–28.4 °C, salinity 22–24‰, and pH 7.80–8.12. Compensatory growth occurred in the smallest size-group after 7 and 15 d of starvation, respectively. The point-of-no-return (PNR₅₀) was determined to be 18.7 d. However, no compensatory growth was noted in the medium size-group, and the PNR₅₀ for this group was 25.2 d. The complete compensatory growth was observed for the largest size-group following food depravation for 7 and 30 d, respectively. In the same group, over-compensatory growth occurred 15 d post-starvation. The PNR₅₀ for the largest size-group was 46.3 d. The survival rate of different groups decreased as the starvation time prolonged. To discuss the change in body biochemical composition of individuals in the process of starvation and refeeding, the biochemical composition of the largest group individuals at different stages was determined. There were no significant differences in moisture and ash concentrations of the largest size-group during starvation and refeeding (P > 0.05). The relative body protein content increased as the starvation period prolonged and the level returned to normal after refeeding. The lipid content of the clam at the end of starvation was significantly lower than the initial level (P < 0.05), and remained below the initial level at end of the refeeding period.     

Energy reserves during food deprivation and compensatory growth in juvenile roach: the importance of season and temperature

The effect of 21 days of starvation, followed by a period of compensatory growth during refeeding, was studied in juvenile roach Rutilus rutilus during winter and summer, at 4, 20 and 27° C acclimation temperature and at a constant photoperiod (12L : 12D). Although light conditions were the same during summer and winter experiments and fish were acclimated to the same temperatures, there were significant differences in a range of variables between summer and winter. Generally winter fish were better prepared to face starvation than summer fish, especially when acclimated at a realistic cold season water temperature of 4° C. In winter, the cold acclimated fish had a two to three‐fold larger relative liver size with an approximately double fractional lipid content, in comparison to summer animals at the same temperature. Their white muscle protein and glycogen concentration, but not their lipid content, were significantly higher. Season, independent of photoperiod or reproductive cycle, was therefore an important factor that determined the physiological status of the animal, and should generally be taken into account when fish are acclimated to different temperature regimes. There were no significant differences between seasons with respect to growth. Juvenile roach showed compensatory growth at all three acclimation temperatures with maximal rates of compensatory growth at 27° C. The replenishment of body energy stores, which were utilized during the starvation period, was responsible for the observed mass gain at 4° C. The contribution of the different energy resources (protein, glycogen and lipid) was dependent on acclimation temperature. In 20 and 27° C acclimated roach, the energetic needs during food deprivation were met by metabolizing white muscle energy stores. While the concentration of white muscle glycogen had decreased after the fasting period, the concentrations of white muscle lipid and protein remained more or less constant. The mobilization of protein and fat was revealed by the reduced size of the muscle after fasting, which was reflected in a decrease in condition factor. At 20° C, liver lipids and glycogen were mobilized, which caused a decrease both in the relative liver size and in the concentration of these substrates. Liver size was also decreased after fasting in the 4° C acclimated fish, but the substrate concentrations remained stable. This experimental group additionally utilized white muscle glycogen during food deprivation. Almost all measured variables were back at the control level within 7 days of refeeding.     

短期饥饿和再投喂对岩原鲤仔鱼生存生长以及RNA/DNA和RNA/蛋白质比率的影响(英文)

研究通过对岩原鲤仔鱼在饥饿和再投喂条件下其生存、生长率、RNA/DNA和RNA/蛋白质比率的测定,评估了仔鱼对饥饿的耐受能力和恢复能力。在(19.5±0.5)℃水温下,将岀膜后第16天的岩原鲤仔鱼随机分成6个组:1个持续投饲对照组,实验组分别禁食1、2、3、4、5d后再投喂,实验共进行10d。每天分别从各组取9尾鱼测定体重、体长、RNA、DNA、蛋白质含量。实验结果显示,饥饿处理组仔鱼存活率和以上各项生长指标均随饥饿时间的增加而下降,在恢复投喂后均表现不同程度的补偿生长,其中饥饿1、2、3d的仔鱼在恢复投喂后显示出完全补偿生长,几乎弥补了饥饿所产生的影响,平均终体重与对照组比较无显著差异。饥饿4、5d的仔鱼显示部分补偿生长,恢复投喂只少量减轻了饥饿的影响,平均终体重与对照组相比存在显著差异。饥饿1、2、3d的仔鱼和4、5d的仔鱼在恢复投喂后分别需要1—2d和4d时间才能达到与对照组无显著差异水平。仔鱼生长率变动范围从0.59%到8.00%WW/day,仔鱼RNA/DNA比率、RNA/蛋白质比率与生长率的回归方程为:GR=3.63RNA/DNA 1.74(R2=0.80)和GR=120.14RNA/Protein 2.33(R2=0.31),两种比率均与生长率呈显著线性相关,RNA/DNA比率对生长变化的拟合度更好。结果表明,仔鱼阶段食物缺乏很可能是影响岩原鲤仔鱼存活、生长的主要因素。RNA/DNA更适合作为评定岩原鲤仔鱼营养条件和生长的指标。     

Effect of different starvation and refeeding periods on macromolecules in the haemolymph,digestive parameters,and reproductive state in Aegla platensis (Crustacea,Decapoda, Aeglidae)

In the present study we assessed the effects of different periods of starvation and refeeding on macromolecule levels (glucose, proteins, triglycerides, and glycerol) in the hemolymph as well as circulating levels of cholesterol in Aegla platensis. We also studied possible changes in the distribution of stomach fullness classes (DSFC), mean stomach fullness degree (SFD), and the mean stomach fullness, hepatosomatic, and gonadosomatic indices. Animals were collected in the field, sexed and divided into groups. This was made as follows: lab control (10 days on standard diet); 5, 15, and 30 days starvation; and 5 days refeeding. During the starvation period there were differences in cholesterol, glucose, and proteins in both genders, but we observed no differences in total lipid, triglycerides, or glycerol levels. The SFD was the lowest in the 30-day starvation group in both females and males. Starvation appears to modulate gastric emptying and possibly digestive processes as well as induce preferential utilization of carbohydrates and proteins. This enables survival throughout the study period. We observed maintenance of gonadosomatic index and reduction of hepatosomatic index in females during the study period with a return to baseline after refeeding. Refeeding was insufficient to restore the DSFC, but sufficient to restore glucose and cholesterol levels.     

Effect of starvation and refeeding on digestive enzyme activities in juvenile roach, Rutilus rutilus caspicus

We evaluated the effects of starvation and refeeding on digestive enzyme activities in juvenile roach, Rutilus rutilus caspicus. Fish were divided into four feeding groups (mean mass 1.68 ± 0.12 g). The control group was fed to satiation twice a day throughout the experiment with formulated diet (SFK). The other three groups were deprived of feed for 1(S1), 2(S2), and 3(S3) weeks, respectively, and then fed to satiation during the refeeding period. The results showed that trypsin specific activity was not affected significantly either by starvation or refeeding, in all experimental groups. Chymotrypsin specific activity did not change significantly in S1 fish during the experimental period. In S2 and S3 fish no significant changes were observed during the starvation period. Upon refeeding, the activity increased in S2 fish, while it decreased in S3 fish. Amylase specific activity decreased significantly during the starvation period in all experimental groups. Upon refeeding, the activity increased. Alkaline phosphatase specific activity did not change significantly during the experiment period in S3 fish, while it showed significant changes during the starvation and refeeding period in the S1 and S2 fish. Starvation also had a significant effect on the structure of the intestine.     

周期性饥饿再投喂对长蛸存活、生长以及肌肉脂肪酸和氨基酸的影响

在19.8—22.2℃条件下, 采用周期性饥饿再投喂的方法, 研究不同投喂模式对长蛸[Octopus minor, 初始体重(94.29±9.35) g, 初始胴背长(53.25±5.25) mm]的存活、生长以及脂肪酸和氨基酸的影响。实验分为4个组包括对照组(持续投喂)、S₁F₅组(周期性饥饿1d再投喂5d)、S₂F₄组(周期性饥饿2d再投喂4d)和S₃F₃组(周期性饥饿3d再投喂3d), 持续24d。实验结果如下: 随饥饿时间的延长, 增重率、肝体比、体重变化量以及终末体重四个指标均呈现出先上升后下降的趋势, 其中S₁F₅组的值均显著高于对照组, 而S₃F₃组的值除肝体比外均显著低于对照组。长蛸的成活率随饥饿时间的增长呈现出下降趋势, 但各实验组均与对照组差异不显著; 摄食量随饥饿时间的延长, 表现出上升趋势, 且三个实验组的值均显著高于对照组。在长蛸肌肉脂肪酸中, 饱和脂肪酸(SFA)、不饱和脂肪酸(UFA)、单不饱和脂肪酸(MUFA)以及多不饱和脂肪酸(PUFA)的含量均与对照组差异不显著, 但S₁F₅组的值与对照组相比出现了一定程度的升高; 在氨基酸含量上, 各实验组的必需氨基酸总量(TEAA)、氨基酸总量(TAA)以及必需氨基酸总量/氨基酸总量(TEAA/TAA)的值均与对照组差异不显著。综上所述, S₁F₅组和S₂F₄组长蛸出现了补偿生长现象, 且S₁F₅组长蛸具备超补偿生长能力。因此, 在长蛸的人工养殖过程中, 为保证其养殖效果, 建议采用周期性饥饿1d再投喂5d的投喂模式。     

Compensatory growth in sub‐yearling Siberian sturgeon,Acipenser baerii Brandt, 1869: Effects of starvation and refeeding on growth,feed utilization and body composition

The capacity of sub‐yearling Siberian sturgeon (Acipenser baerii Brandt, 1869) (19.7 ± 0.8 g) to show compensatory growth was assessed for a 40‐day period for the effects of short‐term starvation and refeeding on growth, feeding performance and body composition. After acclimation, 25 experimental fish were randomly distributed among twelve 500‐L cylindrical fiberglass tanks with a flow‐through system. The fish were subjected to four different feeding regimes: control, which was fed four times daily to apparent satiation; T₁: four periods of 2 days starvation alternating with 8 days re‐feeding; T₂: two periods of 4 days starvation alternating with 16 days refeeding; T₃: an 8 days starvation period followed by 32 days refeeding. At the end of the experiment, the deprived fish attained body weights comparable to those attained by the control fish. There were no differences in growth and feeding performances between the deprived and the control fish. Total protein and lipid contents of the control fish were significantly higher than that of T₁ and T₂ fish at the end of the experiment (P < 0.05). A significant difference in the energy content was observed between T₂ and the control. Siberian sturgeon exhibited complete compensation, indicating a high ability of the deprived fish to grow sufficiently to fully compensate for weight loss during starvation. The results suggested that the feeding schedule involving starvation–refeeding cycles could be a promising feed management option for the culture of this species.     

草地贪夜蛾幼虫耐饥力及饥饿对其生长发育和繁殖的影响

本文旨在明确草地贪夜蛾Spodoptera frugiperda(J.E.Smith)幼虫耐饥力及饥饿处理对其生长发育、繁殖力的影响.选取初孵幼虫(幼虫孵化1 h内)、2、4、6、8和10日龄的幼虫进行饥饿处理,测定存活率和存活时间分析其耐饥力;进一步选取8日龄幼虫分别饥饿1、2、3和4d后再复食,分别统计和分析饥饿胁...     

Effects of starvation on larval growth, survival, and metamorphosis of Manila clam Ruditapes philippinarum

The effects of starvation on larval growth, survival, and metamorphosis of Manila clam Ruditapes philippinarum at the temperature of 19.6–21.6 °C, the salinity of 34‰ and pH of 8.0 were investigated from May 18 to July 18, 2006. In this study, the early, middle and late umbo-veliger larvae with the shell lengths of 100, 140, and 190 μm were subject to temporary food deprivation for up to 4.5, 20, and 25d at 0.5, 4, 5d intervals, followed by refeeding for the remaining of a 24, 20, 25d period, respectively. The results suggested that the larvae should have shown considerable tolerance to starvation due to their endogenous and exterior nutrition material, for larvae and time to the point-of-no-return (PNR: the threshold point during starvation after which larvae could no longer metamorphose even if food is provided) were calculated to be 4.25, 17.54, and 22.17d. As the starvation period prolonged, the mean shell length of larvae starved got close to constants at 1.5, 4, and 15d after starvation, which were different for larvae at different stages when starvation began, survival of larvae decreased, and was lower in treatments starved earlier in development than those starved later, for the early, middle and late umbo-veliger larvae, after 4.5, 20 and 25d of starvation period, few larvaes were alive. After starvation period, the alive larvaes were able to metamorphose and had a capability of compensatory growth when refeeding was given. Starvation not only affected metamorphosis rate, but also caused the delay in the time to metamorphosis and the decrease in the metamorphosed sizes. For example, for the continuously-fed larvae, duration to metamorphosis was 20.7d, for larvae with a size of 100-μm starved for up to 4d, larvae with a size of 140-μm starved for up to 16d, larvae with a size of 190-μm starved for up to 20d, duration to metamorphosis were 29.7, 31.7, and 37.7d, the delay in duration to metamorphosis were 9, 11, and 17d, respectively. Furthermore, importance of nutrition material for maintaining larval survival during starvation and the compensatory growth on larvae at the same feeding time were discussed.     

越冬饥饿胁迫对草鱼机体生化组成和糖脂蛋白代谢相关基因转录水平的影响

为了探讨草鱼(Ctenopharyngodon idellus)在越冬期间能量利用的代谢适应机制, 将草鱼初始体重[(1053.33±16.11) g]置于室外水泥培育池, 分别在自然越冬饥饿0、1、2、4、8、12和16周后进行采样, 进行肌肉常规成分、血清能量代谢物、组织糖原、甘油三酯含量及AMP活化蛋白激酶和糖脂蛋白代谢相关基因转录水平的检测。结果显示: 越冬饥饿1周后, 草鱼肌肉各常规成分含量显著变化(P<0.05); 随着越冬饥饿时间的延长, 血清甘油三酯(TG)、甘油(Glycerol)、总蛋白(TP)、总胆固醇(TCHO)和血糖(GLU)含量先显著降低(P<0.05), 随后保持稳定, 游离脂肪酸(Free fatty acids)含量显著上升(P<0.05); 肝胰脏糖原和肌肉糖原及肝胰脏、肌肉和脂肪组织TG含量显著降低(P<0.05); 血清ATP、ADP和AMP含量显著降低, ADP+AMP/ATP比值显著升高(P<0.05); 肝胰脏、肌肉及腹腔脂肪ampk α1、ampk α2基因表达显著上升(P<0.05), 下游糖脂及蛋白代谢相关基因转录水平显著上升(包括atgl、hsl、cpt1α、cd36等脂分解相关基因; gk、pfk、pk等糖酵解相关基因; gldh、 igf-1等蛋白分解相关基因)或显著下调(acc、fas等脂合成相关基因; creb、foxo1、pgc-1α、pepck、g6pase、glut2等糖异生相关基因; tor、s6k等蛋白合成相关基因)(P<0.05)。研究表明, 草鱼在越冬饥饿期间, 血清、肝胰脏、肌肉和脂肪组织生化组成发生了上述变化的同时, 越冬饥饿胁迫激活了AMPK通路, 促进了各组织糖酵解、脂质分解、脂肪酸β氧化、脂肪酸转运及蛋白分解的进程, 抑制了糖原合成、脂质合成和蛋白合成的过程, 进而维持了机体能量稳态。