丙氨酰—谷氨酰胺和维生素E对军曹鱼的影响

本研究探讨了添加不同剂量和比例的丙氨酰—谷氨酰胺和维生素E对军曹鱼幼鱼相对质量增加率、特定生长率和不同组织器官RNA/DNA比值的影响。在饲料中添加不同剂量和比例的丙氨酰—谷氨酰胺和/或维生素E,饲喂军曹鱼幼鱼12周后,称其体质量,计算相对质量增加率和特定生长率,测定肝脏、肌肉、脑、心脏、肾和血清的RNA和DNA含量,计算RNA/DNA比值。将鱼特定生长率与各组织器官RNA/DNA比值做线性回归方程分析,比较二者的相关性。结果显示,添加丙氨酰—谷氨酰胺、维生素E可促进幼鱼的特定生长率。试验鱼主要组织器官RNA/DNA比值与特定生长率的线性回归相关系数r2的大小为肌肉血清肝脏肾心脏脑。其中鱼肉RNA/DNA比值与其特定生长率的线性回归相关系数r2=0.8422,血清RNA/DNA比值与特定生长率的线性回归相关系数r2=0.82705,均呈高度正相关。由此得出结论,在本试验条件下,添加丙氨酰—谷氨酰胺和/或维生素E可促进军曹鱼幼鱼的相对质量增加率和特定生长率,也增加其主要组织器官RNA/DNA比值;当每千克干饲料添加丙氨酰—谷氨酰胺5g和维生素E 50IU时,效果最佳。军曹鱼幼鱼的特定生长率与其肌肉、血清的RNA/DNA比值高度正相关,可互为指示。     

草鱼幼鱼对异亮氨酸的需要量

以初始体重（8.25±0.37） g的草鱼幼鱼为试验对象,分别采用异亮氨酸（isoleucine,Ile)水平为0.77 %、1.07 %、1.37 %、1.67 %、1.97 %和2.27 % 6组等氮(粗蛋白35.25 %)半纯化日粮对草鱼进行了72 d生长试验,研究其日粮异亮氨酸需要量。结果表明：（1）日粮Ile水平为1.67 %时,草鱼增重率、特定生长率和蛋白质效率最高,饲料系数最低;鱼体空壳率和肥满度达到最大值,内脏指数最小;草鱼体水分、体脂最低,体蛋白、灰分最高;肌肉水分最低,粗蛋白最高。而各水平之间肌肉粗脂肪无显著差异(P> 0.05);日粮Ile水平为1.67 %时,草鱼肌肉Ile含量和肌肉氨基酸总量最高。（2）随日粮Ile水平增加,肌肉RNA/DNA呈先升后降趋势,Ile 1.67 %水平组最高;而肝脏谷氨酸脱氢酶却呈先降后升趋势,Ile 1.67 %水平组最低。血氨在Ile 0.77 % ~ 1.67 %水平组之间处于稳定状态,高于1.67 %水平后呈上升趋势。血清白蛋白受日粮Ile水平的影响不显著（P> 0.05）。（3）随日粮Ile水平增加,血清甘油三酯和胆固醇均呈先降后升趋势,且在Ile 1.67%水平组,两项指标均为最低值,显著低于其他水平组（P< 0.05）。根据增重率、特定生长率、饲料系数和蛋白质效率与日粮Ile水平的二次曲线关系,确定草鱼幼鱼日粮(粗蛋白35.25 %) Ile适宜需要量范围为1.41 %～1.49 %(日粮基础)或4.0 %～4.23 %(日粮蛋白基础)。     

不同脂肪(能量)蛋白比饲料对梭鲈幼鱼生长的影响

比较了5种不同脂肪(能量)蛋白比的配合饲料对初始平均体重(7.75±1.17)g梭鲈幼鱼生长性能的影响。结果表明,投喂不同脂肪蛋白水平的饲料,以能量蛋白比为45.94kJ/g试验组的生长速度最快[SGR为(2.86±0.17)%/d]、饲料系数最低(FCR为1.57±0.12)、蛋白质沉积率和能量保留率最大,分别为98.44%±2.38%和30.88%±3.83%;以饲料中蛋白质含量、脂肪含量为变量因子,以梭鲈幼鱼的特定生长率、蛋白质沉积率和能量保留率为指标,通过二元二次回归方程得出梭鲈最大生长速度时饲料中蛋白质含量为39.80%,脂肪含量为8.79%,总能为18.53MJ/kg,脂肪蛋白比为0.22,能量蛋白比为46.56kJ/g;梭鲈获得最大的蛋白质沉积率时,饲料蛋白质含量为38.76%,脂肪含量为9.18%,总能为18.65MJ/kg,脂肪蛋白比为0.24,能量蛋白比为48.12kJ/g;梭鲈获得最大的能量保留率时饲料蛋白质含量为38.55%,脂肪含量为9.45%,总能为18.72MJ/kg,脂肪蛋白比为0.25,能量蛋白比为48.56kJ/g;饲料中脂肪水平的增加可以降低鱼类耗能时对蛋白质的需求量,表...     

不同投饲率对锦鲤幼鱼生长及鱼体生化成分的影响

采用同一种饲料,选取同批次的锦鲤幼鱼(17.50±1.04)g,研究投饲率对锦鲤幼鱼生长及鱼体生化成分的影响,分别设置5个投喂水平(鱼体质量1.0%、2.0%、3.0%、4.0%、5.0%),在水温为(27.0±1.0)℃的条件下40 d的养殖试验结果表明:随着投饲率的增加,特定生长率和相对增重率呈先上升后平稳的趋势,饲料利用率呈先下降后平稳再下降趋势;随着投饲率的增加,鱼体的粗蛋白、粗脂肪和灰分含量逐渐上升,而水分含量逐渐降低。根据相对增重率和饲料利用率综合分析,确定锦鲤幼鱼适宜投饲率在水温(27.0±1.0)℃时为4.0%。     

草鱼幼鱼的饲料苏氨酸需要量

选用初始体质量为(8.35±0.06)g的草鱼(ctenopharyngodon idella)540尾,随机分成6组,每组3个重复,每个重复30尾鱼,分别饲喂苏氨酸水平为0.72%、1.02%、1.32%、1.62%、1.92%和2.22%(占饲料的质量分数)的6组等氮半精制饲料(蛋白质质量分数35%),经60 d生长实验确定草鱼幼鱼的苏氨酸需要量.实验结果表明,随着饲料苏氨酸水平增加,草鱼的增重率、特定生长率、蛋白质效率、蛋白质沉积率、肌肉RNA/DNA比值和血氨水平显著升高(P<0.05),均在1.62%组达到最大值;饲料系数和肝脏谷氨酸脱氢酶活力显著降低(P<0.05),均在1.62%组达到最小值;随着饲料苏氨酸水平进一步提高,上述指标不再发生显著变化(P>0.05).随饲料中苏氨酸水平的增加,草鱼血清总蛋白浓度显著升高,1.32%、1.62%和1.92%3组显著高于0.72%和1.02% (P<0.05),2.22%组达最大值,并显著高于其他各组(P<0.05);血清甘油三酯和胆固醇浓度在饲料苏氨酸水平为1.32%～2.22%的4组间没有显著差异(P>0.05),但显著高于0.72%组和1.02%组(P<0.05).饲料中苏氨酸水平为1.62%时,草鱼肌肉苏氨酸含量和肌肉氨基酸总量均为最大值,显著高于其他各组(P<0.05).饲料苏氨酸适宜水平能使草鱼全鱼水分显著降低,增加蛋白质、脂肪和灰分含量(P<0.05),同时降低草鱼肌肉水分,增加蛋白质含量(P<0.05),但不影响脂肪含量(P>0.05).饲料中苏氨酸水平对草鱼肝脏谷丙转氨酶、谷草转氨酶活力无显著影响(P>0.05).以特定生长率、饲料系数、蛋向质沉积率、肌肉RNA/DNA和谷氨酸脱氢酶活力分别对饲料苏氨酸水平进行折线同归分析,并以这些指标达95%最佳值时为判断依据,得出草鱼幼鱼饲料中苏氨酸适宜需要量以占饲料的质量分数计为1.42%～1.61%(饲料蛋白质质量分数35%)或以占饲料蛋白质的质量分数为4.07%～4.60%.     

杂交鲟幼鱼饲料中有效磷需要量的研究

为研究杂交鲟(Acipenser baerii♀×Acipenser schrenckii♂)幼鱼对饲料中有效磷的需要量,实验以磷酸二氢钙为磷源,配制了有效磷水平分别为0.37%(对照组)、0.65%、0.96%、1.22%和1.48%的5组等氮等能饲料。每组饲料设置3个重复,每个重复22尾鱼,饲喂初重(10.06±0.39)g杂交鲟幼鱼8周。结果显示:(1)饲料中不同有效磷水平对实验鱼的成活率、肝体比、脏体比和肥满度均无显著影响。随饲料有效磷水平增加,实验鱼的增重率和特定生长率呈先升高后趋于平稳的趋势,0.96%、1.22%和1.48%组增重率和特定生长率均显著高于0.37%组和0.65%组;全鱼粗脂肪含量呈降低趋势;饲料效率和蛋白质效率均呈先升高后降低的趋势。(2)不同有效磷水平饲料对全鱼水分、粗蛋白和肌肉水分、粗蛋白、粗脂肪、粗灰分、磷含量均无显著影响。0.96%、1.22%和1.48%组全鱼粗灰分、磷含量和脊椎粗灰分、磷含量均显著高于0.37%组和0.65%组。(3)随饲料有效磷水平增加,实验鱼血清磷含量和碱性磷酸酶活性均呈先升高后趋于平稳的趋势。0.96%、1.22%和1.48%组血清磷含量显著高于0.37%组和0.65%组,对照组的碱性磷酸酶活性显著低于其他组。(4)分别利用折线模型拟合分析实验鱼的增重率、全鱼磷含量和脊椎磷含量与饲料有效磷水平的相关性,得到饲料中适宜有效磷需要量分别为0.93%、1.02%和0.95%。综上所述,建议杂交鲟幼鱼饲料中有效磷添加水平为0.93%~1.02%为最佳。     

不同投饵率对暗纹东方鲀幼鱼生长的影响

比较投饵率水平分别为3%、4%、5%、6%时,对暗纹东方鲀幼鱼生长、饲料效率的影响,以确定暗纹东方鲀幼鱼阶段的适宜投饵率。在23℃下,对规格为3.45～3.56g的暗纹东方鲀幼鱼进行30d的生长实验,结果表明:不同投饵率对暗纹东方鲀幼鱼的特定生长率、质量相对增加率、饲料效率、存活率均有显著影响(p<0.05);暗纹东方鲀幼鱼的适宜投饵率为4%,在投饵率为4℅时,质量相对增加率为116.04±0.04%,饲料效率达83.70±0.02%,特定生长率为111.49±0.03%/d,存活率为84.44±0.02%。     

饲料脂肪水平对江黄颡鱼幼鱼生长性能的影响

研究了饲料中脂肪水平对江黄颡鱼幼鱼(平均体重0.44g)生长性能的影响。实验共设5个水平组,饲料脂肪水平分别为3.77%,4.82%,7.29%,8.37%,9.87%。每组20尾,3个平行,饲养66d。结果显示:随着饲料脂肪水平的升高,江黄颡鱼幼鱼的饲料系数呈上升趋势,蛋白质效率则呈下降趋势,增重率和特定生长率呈抛物线变化,但饲料系数和蛋白质效率差异不显著(P0.05),增重率和特定生长率差异显著(P0.05)。江黄颡鱼幼鱼肝脏中脂肪的蓄积量随饲料中脂肪水平的增加而增加。综合各项指标并分析增重率、特定生长率与脂肪水平的回归性关系,可以推测江黄颡鱼幼鱼期的饲料脂肪水平应该维持在7.59%~7.65%。     

饲料脂肪水平对胭脂鱼幼鱼生长、体组成和抗氧化能力的影响

试验选用体重(6.73±0.21)g的胭脂鱼(Myxocyprinus asiaticus)幼鱼540尾,随机分成6个组,每组3个重复,每个重复30尾试验鱼。以大豆油为脂肪源,配制成脂肪水平为2.04%、4.43%、6.88%、9.02%、11.98%、13.39%的半精制饲料,进行为期56 d的生长试验,研究脂肪水平对胭脂鱼幼鱼生长、体组成及机体抗氧化能力的影响。结果显示:饲料脂肪水平对胭脂鱼的生长性能有显著影响(P<0.05)。脂肪水平为6.88%时,胭脂鱼增重率、特定生长率、蛋白质沉积效率最高,饲料系数最低。脂肪沉积效率随脂肪水平的增加呈下降趋势。随脂肪水平增加,胭脂鱼全鱼、肌肉和肝胰脏脂肪含量逐渐上升,至6.88%组后稳定,而全鱼水分、粗蛋白含量没有显著变化(P>0.05)。胭脂鱼机体抗氧化能力随着脂肪水平的增加呈现先升后降趋势,脂肪水平为6.88%时,总抗氧化能力(T-AOC)、超氧物歧化酶(SOD)值最大,丙二醛(MDA)值最小,即抗氧化能力最强。以增重率、特定生长率和饲料系数进行回归分析并考虑脂肪水平对胭脂鱼营养组成和抗氧化能力的影响,确定胭脂鱼幼鱼适宜脂肪水平为6.62%~7.02%。     

壳寡糖与低聚木糖对大菱鲆(Scophthalmus maximus)幼鱼生长、体组成和血液生化指标的影响

本研究以初始体重为(15.46±0.06) g的大菱鲆(Scophthalmus maximus)幼鱼为实验对象,采用2×3双因素实验设计,研究饲料中壳寡糖(Chitosan oligosaccharide,COS)和低聚木糖(Xylo-oligosaccharide,XOS)对大菱鲆幼鱼生长、体组成和血液生化指标的影响。养殖实验在全封闭循环水养殖系统中进行,养殖周期为60 d。9组实验饲料粗蛋白和粗脂肪含量分别为53%和11%;每组饲料随机投喂3桶,每桶30尾鱼。结果显示,饲料中同时添加0.5%的壳寡糖、1.0%的低聚木糖对大菱鲆幼鱼的促生长作用最明显,相对增重率显著提高。饲料中壳寡糖和低聚木糖对大菱鲆幼鱼增重率、特定生长率、饵料系数、蛋白质效率均有显著影响(P<0.05),但对大菱鲆体成分影响不显著(P>0.05);低聚木糖和壳寡糖对大菱鲆幼鱼特定生长率、增重率、全鱼粗脂肪和灰分、血清甘油三酯、溶菌酶以及碱性磷酸酶均存在显著交互作用(P<0.05)。研究表明,低聚木糖和壳寡糖配合使用可以显著提高大菱鲆幼鱼的生长效果,并且可在一定程度上增强其非特异性免疫能力,降低血脂含量。     

Optimum Dietary Protein Levels and Protein to Energy Ratios in Olive Flounder Paralichthys olivaceus

The olive flounder Paralichthys olivaceus is one of the most commercially important fish species in Korea. In order to formulate better diets for cultured olive flounder we evaluated the optimum dietary protein requirements for larval, fry and juvenile olive flounder, and the optimum dietary protein to energy ratio for juvenile olive flounder. Results of four separate experiments suggested that the optimum dietary protein requirements were 60% in larvae (0.3 g), 46.4–51.2% in 4.1-g juvenile, and 40–44% in 13.3 g growing olive flounder. The optimum dietary protein to energy ratio based on weight gain, feed efficiency, specific growth rate, and protein retention efficiency was 27–28 mg protein/kJ 2 energy (35 and 45% CP for diets containing 12.5 and 16.7 kJ energylg diet, respectively).     

Optimum Dietary Protein Level and Protein-to-Energy Ratio for Growth of Juvenile Korean Rockfish Sebastes schlegeli

An 8-wk feeding trial was conducted to estimate the optimum dietary protein level and protein-to-energy (P/E) ratio in juvenile Korean rockfish Sebastes schlegeli. Twenty experimental diets were formulated with four energy levels and five protein levels at each energy level. Four gross energy levels of 14.2, 16.5, 18.6, and 20.9 kJ/g diet were included at various crude protein (CP) levels. Diets containing CP at 30, 40, 45, 50, and 55% had either 14.2 or 16.5 kJ/g energy; those with CP levels of 35, 40, 45, 50, and 60% had either 18.6 or 20.9 kJ/ g energy. After 2 wk of conditioning, fish initially averaging 7.3 ± 0.04 g (means ± SD) were randomly distributed into net cages as groups of 20 fish. Each diet was fed to fish in three randomly selected net cages for 8 wk. After 8 wk of the feeding trial, weight gain (WG) of fish fed 50% and 55% CP with 14.2 kJ/g diet was significantly higher than those of fish fed 30% and 40% CP diets (P 0.05). WG of fish fed 45, 50, and 55% CP with 16.5 kJ/g diet was significantly higher than those of fish fed 30% and 40% CP diets (P < 0.05). WG of fish fed 60% CP with 18.6 kJ/g diet was significantly higher than those of fish fed 35, 40, and 45% CP diets. WG of fish fed 45% CP with 20.9 kJ/g diet was significantly higher than those of fish fed 35, 40, and 60% CP diets. Generally, feed efficiency (FE) and specific growth rate (SGR) showed a similar trend as WG. However, protein efficiency ratio (PER) was negatively related to dietary protein levels. WG of fish did not always increase with increasing dietary protein and energy levels. Comprehensive comparison among diets containing 40, 45, and 50% CP with different energy levels indicated that the increase in protein from 40 to 45% significantly increased WG (P < 0.05), but such effect was not significant when protein increased from 45 to 50% at all energy levels. Increasing dietary energy significantly increased WG of fish fed 40% and 45% CP at each energy level; however, there was no difference in WG of fish fed 50% CP with energy levels of 18.6 and 2.9 kJ/g diet. There was no significant difference in WG of fish fed 50% CP with 18.6 kJ/g or 45 and 50% CP with 20.9 kJ/g diet. Broken-line analysis of weight gain indicated that the optimum dietary protein level was 50.9 ± 1.1% and PIE ratio was 35.4 ± 0.8 mg/kJ with 14.2 kJ/g diet; the optimum dietary protein level was 49.3 ± 5.0% and P/E ratio was 30.2 ± 1.0 mg/kJ with 16.5 kJ/g diet; the optimum dietary protein level was 46.2 ± 9.2% and P/E ratio was 24.7 ± 4.9 mg/kJ with 18.6 kJ/g diet; and the optimum dietary protein level was 45.1 ± 1.8% and P/E ratio was 21.5 ±0.7 with 20.9 kJ/g diet. Therefore, these data indicated that the concept of P/E ratio must be restricted to diets containing adequate protein and energy levels. Based on WG, the optimum P/E ratio was between 21.5 and 35.4 mg protein/kJ gross energy in juvenile Korean rockfish when gross energy ranged from 14.2 to 20.9 kJ/g diet.     

Dietary Protein Requirement of Juvenile Cachara Catfish,Pseudoplatystoma reticulatum

Cachara, Pseudoplatystoma reticulatum, is a high commercial value carnivorous catfish in Brazil, but whose dietary protein requirement is still unknown. Aiming to determine this requirement, groups of 15 juveniles (16.08 ± 1.13 g) were fed isoenergetic diets (4600 kcal/kg gross energy) with increasing levels of crude protein (30, 35, 40, 45, 50, and 55%). After 60 d, regression analysis revealed a quadratic effect (P < 0.05) of increasing dietary crude protein concentration on growth variables. The highest weight gain and specific growth rate as well as the best feed conversion were shown by fish fed the 50% crude‐protein diet. Similarly, protease activities were significantly higher (P < 0.05) in fish fed 50% crude protein. However, the highest protein retention was observed in fish fed the 45% crude‐protein diet. Protein and dry matter digestibilities did not differ (P > 0.05) for diets containing 40, 45, or 50% crude protein. Therefore, based on weight gain and at a dietary energy concentration of 4600 kcal/kg, the estimated protein requirement for juvenile cachara between 16 and 85 g is 49.25% crude protein. This is equivalent to 44.79% digestible protein and a gross energy to digestible protein ratio of 10.27 kcal/g.     

大鲵幼体蛋白质的需求量

为评定大鲵幼体对饲料蛋白质的需求量,以鱼粉为主要蛋白源配制6种蛋白质水平(干样基础)的实验饲料:D1(43.7%)、D2(47.1%)、D3(51.3%)、D4(55.7%)、D5(59.9%)和D6(64.4%),饲喂初始体质量为(20.99±0.15)g的大鲵幼体92 d。结果显示,①饲料蛋白质水平对大鲵增重率有显著影响,在D4组达到最大值,较D1组增加了276.4%,且全鲵蛋白质沉积率和肌肉RNA、RNA/DNA值、胃蛋白酶、H^+-K^+-ATPase、胰蛋白酶、脂肪酶和Na^+-K^+-ATPase、肝脏超氧化物歧化酶(SOD)均在D4组达到最佳,而肝脏和肠道丙二醛(MDA)在该组均达到最低;②随饲料蛋白质水平增加,肌肉粗蛋白线性增加,全鲵脂肪线性下降,全鲵水分和粗灰分在各组间差异不显著,全鲵粗蛋白先增加后趋于稳定,在D4组达到最大;③大鲵皮肤胶原蛋白含量在D4组达到最高,较D1组增加了27.83%。研究表明,以增重率、肌肉RNA/DNA值、蛋白质沉积率和皮肤胶原蛋白含量为评价指标,通过二次回归方程分析得到大鲵幼体饲料的最适蛋白质水平为55.9%~58.3%(干样基础),该饲料蛋白质水平能显著提高大鲵幼体胃的泌酸能力、机体消化吸收和抗氧化能力,增加鲵体营养素的沉积,从而促进生长和饲料的转化;而低蛋白质水平饲料显著抑制大鲵的生长。     

Optimum Dietary Protein Level and Protein‐to‐energy Ratio for Growth of Juvenile Parrot Fish,Oplegnathus fasciatus

An 8‐wk feeding trial was conducted to estimate the optimum dietary protein level and protein‐to‐energy (P/E) ratio in juvenile parrot fish, Oplegnathus fasciatus. Eight experimental diets were formulated with two energy levels and four protein levels for each energy level. Diets containing crude protein (CP) at 35, 40, 45, and 50% had either 12.5 or 14.6 kJ/g of energy. Fish averaging 7.1 ± 0.06 g (mean ± SD) were fed one of the experimental diets for 8 wk. At the end of the feeding trial, weight gain (WG) of fish fed 45 and 50% CP in the 12.5 kJ/g diet was significantly higher than fish fed the 35% CP diet (P < 0.05). WG of the fish fed 45 and 50% CP in the 14.6 kJ/g diet was significantly higher than fish fed the 35 and 40% CP diets (P < 0.05). Fish fed the 14.6 kJ/g diet had a higher WG compared with fish fed the 12.5 kJ/g diet at all CP levels. Feed efficiency (FE) and specific growth rate (SGR) showed a similar trend to the WG. WG, FE, and SGR improved with increasing dietary protein levels up to 45% and remained constant at 50% CP for both energy levels. However, protein efficiency ratio was negatively related to dietary protein levels. The results suggested that the optimum level of protein and the optimum P/E ratio for juvenile parrot fish should be 45% and 31.1 mg protein/kJ, respectively, in a diet containing 14.6 kJ/g energy.     

Dietary Lipid Utilization by Juvenile Summer Flounder Paralichthys dentatus

The ability of juvenile summer flounder Paralichthys dentatus to utilize dietary lipid as energy, and the effect of dietary lipid on weight gain and body composition was investigated in a 12-week feeding trial. Diets were formulated to provide 55% crude protein from herring meal and casein. Menhaden oil was added to produce diets with 8, 12, 16 or 20% total lipid while providing 16.0 kJ available energy/g dry diet. The diet containing 20% total lipid supplied 16.7 kJ available energy/g dry diet due to the high levels of protein and lipid. An additional diet was included to reproduce currently available commercial diet formulations for flounder, providing 55% crude protein supplied solely from herring meal and 16% total dietary lipid. Juvenile summer flounder (initial weight 23 g) were stocked into triplicate aquaria in a closed, recirculating system maintained at 20 C. Fish were fed 2% of body weight each day divided into two equal feedings. Upon termination of the study, effects of dietary lipid on weight gain, body condition indices, and proximate composition were determined. Weight gain (96–149% of initial weight), feed efficiency ratio values (0.43–0.48). fillet yield, and whole-body composition all were unaffected by dietary lipid level. High levels of dietary lipid did increase the lipid content in the finray muscle, as fish fed diets containing 16 and 20% dietary lipid had significantly higher lipid levels than fish fed the diet containing 8% lipid. No apparent protein sparing effect of lipid was observed. These data indicate that currently available commercial feeds for summer flounder may be over-formulated and show a need for further research to determine specific and accurate nutritional information for this species.     

饲料蛋白能量比对草鱼幼鱼生长性能、蛋白利用和体成分的影响

以鱼粉和豆粕为蛋白源,鱼油和豆油等比例混合油为脂肪源,采用4×4因子实验来确定草鱼(Ctenopharyngodon idellus)幼鱼饲料中的合适蛋白能量比(P/E),其中饲料蛋白水平分别为20%、25%、30%、35%,能量水平为12.5、13.7、15、16.2 k J/g,饲料蛋白能量比的范围为12.1~27.3 mg/k J,共16组饲料,每组设3个重复,连续投喂初体质量(16.85±0.29)g的草鱼幼鱼10周,研究饲料蛋白能量比对草鱼幼鱼生长性能、蛋白利用和体成分的影响。结果表明:(1)最高末体质量和特定生长率出现在P/E为18.3 mg/k J组,而P/E为16.0 mg/k J组的饲料系数最高,蛋白质效率和蛋白沉积率最高组分别为P/E 12.10 mg/k J组和15.20 mg/k J组。(2)P/E为27.30 mg/k J组的能量沉积率和总氮排泄率最大。(3)在同一饲料蛋白水平下,鱼体的脂肪含量随饲料能量水平升高而升高;在同一饲料能量水平下,鱼体的蛋白含量随饲料蛋白含量升高而升高。对生长、蛋白利用、体成分的实验结果进行综合分析,草鱼幼鱼饲料的最适蛋白含量为30%,最适P/E为19.5 mg/k J。     

Effect of varying dietary energy level on feed intake, feed conversion, whole-body composition and growth of Malawian tilapia, Oreochromis shiranus– Boulenger

Four isonitrogenous [30% crude protein (CP)] diets containing different gross energy levels (13.39, 16.74, 20.50 and 23.85 kJ g⁻¹) were evaluated to determine the optimum energy for the Malawian tilapia Oreochromis shiranus. Each tank (120 L) was stocked with 18 juvenile tilapia (average weight 7.32±0.25 g) and they were fed the experimental diets for 10 weeks. The final average weight of the fish was approximately twofold higher (range: 12.64–16.77 g) than the initial weight. The dietary energy significantly (P<0.05) influenced growth. The average weight of fish fed dietary energy level 20.50 kJ g⁻¹ was significantly higher (P<0.05) than the weight of the fish fed any of the other experimental diets. There was no significant difference in growth of fish fed 13.39 and 16.74 kJ g⁻¹ energy levels, but 23.85 kJ g⁻¹ produced the lowest growth rates. There were no significant differences (P>0.05) between feed intake across the treatments. Feed conversion ratio (range: 2.2–3.0) and protein efficiency ratio (range: 1.10–1.50) among the dietary treatment groups were in agreement with trends for weight gain. Dietary energy level significantly (P<0.05) influenced the body composition of O. shiranus. Whole‐body moisture (range: 64.27–67.15%) and ash (range: 13.21–14.73%) decreased in all treatments. Whole‐body protein (range: 63.57–66.16%) increased only in groups fed on the diet containing 20.50 kJ g⁻¹. Whole‐body fat (range: 13.58–17.27%) and gross energy (range: 28.411–33.210 kJ g⁻¹) increased significantly (P<0.05). Fish survival was 100% in all treatments. The results demonstrated that to maximize growth at a temperature of 23°C, O. shiranus should be fed diets containing 20.50 kJ g⁻¹ gross energy.     

Evaluation of Growth Performance and Whole-body Composition of Juvenile Hybrid Striped Bass Morone chrysops × Morone saxatilis and Red Drum Sciaenops ocellatus Fed High-protein and High-lipid Diets

To investigate potential use of increasing nutritional density of diets for rapid growth of warm‐water fishes, a feeding trial was conducted in which growth performance, body indexes, and whole‐body composition of juvenile hybrid striped bass fed diets comprising protein (49, 54, and 59%), lipid (16, 20, 23, and 28%), and energy (22.0–25.1 kJ/g) concentrations beyond established minimum levels were compared to those of fish fed a more typical commercial reference diet (37.5% crude protein, 10.5% crude lipid, and 19.6 kJ/g energy on a dry matter basis). A subset of the experimental diets and the commercial reference diet also were fed to juvenile red drum. After 6 wk of feeding, hybrid striped bass fed the high‐protein and high‐lipid diets showed much greater growth performance compared to fish fed the commercial diet. Increasing dietary protein level, but not lipid level, tended (P ≤ 0.1) to enhance weight gain and feed efficiency of hybrid striped bass. Hepatosomatic index (HSI), intraperitoneal fat (IPF) ratio, and whole‐body protein were significantly (P < 0.01) influenced by dietary protein level. The dietary lipid and associated energy level had significant negative linear effects on daily feed intake. Linear regression analysis showed that dietary energy : protein ratio, largely influenced by dietary protein level, moderately but significantly influenced weight gain, HSI, IPF ratio, and whole‐body protein of hybrid striped bass and red drum. Red drum grew very similar to hybrid striped bass in response to the experimental diets. However, significant differences in HSI, IPF ratio, whole‐body protein, lipid, moisture, and ash between hybrid striped bass and red drum were observed, indicating species differences in protein and energy partitioning. In particular, the excessive lipid in the diet increased HSI and whole‐body lipid of red drum but not of hybrid striped bass.     

Dietary lysine requirement of fingerling Catla catla (Hamilton) based on growth, protein deposition, lysine retention efficiency, RNA/DNA ratio and carcass composition

A 12-week experiment was conducted to quantify dietary lysine requirement of fingerling Catla catla (3.65 ± 0.05 cm; 0.58 ± 0.02 g) by feeding casein–gelatine-based diets (33.0 % crude protein; 14.3 kJ/g digestible energy) with six levels of l-lysine (1.25, 1.50, 1.75, 2.00, 2.25 and 2.50 % dry diet). The experiment was conducted in eighteen 70-L indoor polyvinyl circular troughs provided with a water flow-through system (1–1.5 L/min). Live weight gain (LWG), feed conversion ratio (FCR), protein deposition (PD), lysine retention efficiency (LRE%) and RNA/DNA ratio were used as the response criteria. Second-degree polynomial regression analysis at 95 % maximum and minimum response of LWG and FCR data exhibited the lysine requirement between 1.8 and 1.9 % dry diet, corresponding to 5.5–5.7 % dietary protein. Regression analysis of PD, LRE and RNA/DNA ratio yielded the requirement between 1.7 and 1.8 % dry diet, corresponding to 5.2–5.5 % dietary protein. Since live weight gain and protein deposition are the key parameters for estimating nutrient requirement, these tools were used to recommend the lysine requirement of fingerling C. catla which ranges between 1.7 and 1.8 % dry diet. Data generated during this study will be useful to formulate lysine-balanced feed for intensive culture of this fish.