饲料中添加L-肉碱对吉富罗非鱼生长、肝脏脂肪代谢及抗氧化能力的影响

分别在3组等氮等能的吉富罗非鱼(GIFT,Oreochromis niloticus)饲料中添加不同水平的L-肉碱[0(对照组)、150和300 mg/kg],试验选用初始体重为(8.21±0.33)g的幼鱼投喂9周,探讨L-肉碱对吉富罗非鱼生长、体成分、血清生化指标、肝脏脂肪代谢酶活性和抗氧化能力的影响。结果表明:添加150或300 mg/kg L-肉碱显著提高了罗非鱼增重率(WGR)和特定生长率(SGR),显著降低了实验鱼肝体比(HSI)和脏体比(VSI);添加150 mg/kg L-肉碱组WGR和SGR最高,HSI和VSI最低。添加150 mg/kg L-肉碱显著提高了鱼体肥满度(CF)。饲料系数(FCR)和存活率(SR)在对照组和实验组间无显著差异。添加150或300 mg/kg L-肉碱显著提高了鱼体肝脏中粗蛋白含量,添加150 mg/kg L-肉碱显著降低了肝脏粗脂肪含量。添加150或300 mg/kg L-肉碱时,血清甘油三酯(TG)含量显著降低,肝脏脂蛋白脂酶(LPL)、肝脂酶(HL)、总酯酶(LPL)和脂肪酶(LPS)活性显著上升,肝脏过氧化氢酶(CAT)和谷胱甘肽过氧化物酶(GSH-PX)活性显著增加,肝脏丙二醛(MDA)含量显著下降。添加300 mg/kg L-肉碱显著提高了鱼体肝脏超氧化物歧化酶(SOD)活性和溶菌酶(LZM)活性。综上,饲料中添加适量L-肉碱对提高吉富罗非鱼生长性能,促进其脂肪代谢和提高鱼体抗氧化能力有良好效果。基于L-肉碱对罗非鱼增重率和特定生长率的影响,推荐L-肉碱在吉富罗非鱼饲料中的添加量为150 mg/kg。     

饲料中添加谷胱甘肽对吉富罗非鱼抗氧化和抗亚硝基氮应激能力的影响

选择初始体重(3.27±0.04)g的吉富罗非鱼(GIFT Oreochromis niloticus),分别投喂基础饲料和添加80、160、240、320和400 mg/kg谷胱甘肽(GSH)的试验饲料,记作G0、G80、G160、G240、G320和G400。49 d后,G320血清和G160、G240肝脏谷胱甘肽S-转移酶,G160、G240血清和G320肝脏谷胱甘肽还原酶,G240肝脏超氧化物歧化酶,G320血清和G240肝脏过氧化氢酶活性,G240～G400血清和G240肝脏总抗氧化能力,G320血清抗超氧阴离子活性,与对照组相比分别显著升高。G80～G320肝脏丙二醛含量显著低于对照组。在亚硝基氮应激96 h内,G320累积死亡率显著降低。结果表明,饲料中添加一定量的GSH能显著提高罗非鱼的抗氧化性能和抗亚硝基氮应激能力。     

蚕蛹替代鱼粉对吉富罗非鱼肌肉营养成分的影响

试验以300尾初始体重为(44.40±0.41)g的吉富罗非鱼(GIFT,Oreochromis niloticus)为研究对象,分别饲喂用蚕蛹(SP)替代0、25%、50%、75%和100%鱼粉(FM)的5种等氮(32%)等脂(5.5%)的饲料(分别命名SP0、SP25、SP50、SP75和SP100,基础饲料中含8%的鱼粉),每组3重复,每重复20尾鱼,在室内循环水养殖系统进行为期8周的生长试验,旨在探讨蚕蛹替代鱼粉对吉富罗非鱼肌肉营养成分的影响。结果表明:随蚕蛹替代水平上升,吉富罗非鱼肌肉粗蛋白、灰分、总氨基酸、必需氨基酸显著下降,肌肉粗脂肪含量无显著差异;较SP0组,SP100组肌肉总氨基酸和必需氨基酸分别下降3.99%和3.46%。随蚕蛹替代量增加,吉富罗非鱼肌肉C18∶3n-3和C20∶5n-3显著上升,C18∶2n-6显著下降;SP100组吉富罗非鱼肌肉C18∶3n-3和C20∶5n-3较SP0组分别上升105.33%和132.72%。结论:蚕蛹替代鱼粉后显著提高了吉富罗非鱼肌肉C18∶3n-3和C20∶5n-3含量,有利于生产富含n-3PUFA的鱼肉产品。     

饲料中添加红景天对吉富罗非鱼耐低温特性的影响

实验采用高山红景天(Rhodiola sachalinensis)作为饲料添加剂,探究其对低温胁迫下的吉富罗非鱼(Oreochromis niloticus,GIFT)的影响。将0.1%、0.2%、0.4%的高山红景天水煎剂粗提干粉分别添加到基础饲料(对照组),用4种实验饲料投喂吉富罗非鱼54 d,然后进行低温胁迫处理并于30、25、20、15和10℃时分别取样。结果显示:水温为10℃时,添加组的成活率为100%,显著高于对照组,添加组血清中的血糖、高密度脂蛋白胆固醇、一氧化氮浓度和肝脏中的丙二醛水平较对照组显著降低;肝脏中的超氧化物歧化酶和谷胱甘肽过氧化物酶的酶活性水平较对照组显著升高,并且添加水平越高,效果越明显。以上结果说明,饲料中添加0.1%的高山红景天粗提干粉即能对提高罗非鱼的抗低温能力起到一定的积极作用,添加0.2%和0.4%的效果更好。     

吉富罗非鱼对饲料中苯丙氨酸的需要量

分别用含6种水平(质量比分别为0.78%、0.95%、1.09%、1.34%、1.51%和1.72%)苯丙氨酸(phenylalanine,Phe)的等氮等能(粗蛋白30.10%,总能17.73 MJ/kg)饲料,在池塘网箱中(实验期间水温为24~32℃)饲喂初始体重为(52.70±1.80)g的吉富罗非鱼60 d,考察饲料Phe对吉富罗非鱼(GIFT,Oreochromis niloticus)生长性能、饲料系数、体成分、部分血清生化指标及前肠消化酶活性的影响,以期获得吉富罗非鱼对饲料苯丙氨酸的需要量。结果表明,随着饲料中Phe水平的升高,吉富罗非鱼的增重率、特定生长率、蛋白质效率、蛋白质沉积率、肥满度、肝体比和脏体比均呈现先上升后下降的趋势,饲料系数呈现先下降后上升的趋势;全鱼粗脂肪和全鱼灰分含量显著上升(P0.05),肌肉灰分含量显著下降(P0.05)。饲料中Phe对全鱼水分和粗蛋白质、肌肉水分、肌肉粗蛋白质和肌肉粗脂肪含量无显著性影响(P0.05);各实验组的肌肉氨基酸含量差异不显著(P0.05)。饲料中Phe显著影响血清中谷丙转氨酶活性,甘油三酯、总胆固醇和葡萄糖的含量(P0.05),对谷草转氨酶活性无显著性影响(P0.05);Phe显著影响肠蛋白酶、肠脂肪酶和肠Na~+-K~+-ATP酶活性(P0.05),而对肠淀粉酶活性影响不显著(P0.05)。以增重率、饲料系数和蛋白质效率为评价指标,通过二次回归分析可知,吉富罗非鱼对饲料中Phe需要量为1.17%~1.21%,占饲料蛋白质的3.89%~4.02%。本研究结果为合理配制吉富罗非鱼配合饲料提供了理论依据。     

吉富罗非鱼对饲料中泛酸的需要量

选用初始体质量为(79.4±1.6)g吉富罗非鱼270尾,随机分成6组(每组3重复,每重复15尾),养殖于500 L养殖桶中,分别饲喂泛酸含量为0.5、4.8、9.5、18.2、36.3和74.4 mg/kg纯化饲料12周,研究确定其对泛酸的需要量。结果表明,随着饲料泛酸含量增加,吉富罗非鱼增重率、肝脏和肌肉泛酸含量均呈先线性增加后稳定的趋势;肥满度和肝体比呈先增加后降低的趋势,均以4.8 mg/kg组最高。全鱼水分含量先降低后增加,全鱼脂肪含量呈现与水分含量相反的趋势。肝总脂含量显著降低,添加组显著低于未添加组(P0.05)。血清高密度脂蛋白含量随着饲料泛酸含量的增加而显著增加(P0.05)。折线回归分析结果表明,吉富罗非鱼(80~350 g)获得最佳生长时对饲料泛酸需要量为10.5 mg/kg,饲料中12.6和13.5mg/kg泛酸可以分别使肝脏和肌肉泛酸累积量达到最大。     

吉富罗非鱼(♀)与翘嘴鳜(♂)远缘杂交子代的遗传特征分析

为了探究吉富罗非鱼(Oreochromis niloticus,GIFT)(♀)与翘嘴鳜(Siniperca chuatsi)(♂)远缘杂交的可行性,对吉富罗非鱼(♀)×翘嘴鳜(♂)子代的胚胎发育、细胞遗传和分子遗传特征进行了初步研究.杂交子代的胚胎存活率仅为(0.34±0.13)％,通过流式细胞技术对正常存活个体进行...     

低剂量糖蜜添加对吉富罗非鱼养殖水质和微生物代谢多样性的影响

为研究低剂量糖蜜添加对吉富罗非鱼(GIFT Oreochromis niloticus)养殖水体水质指标、水体微生物代谢多样性的影响。本实验选取初始体质量为(10±0.13) g的健康吉富罗非鱼,随机分为对照组(C)、10%糖蜜添加组(10S)、20%糖蜜添加组(20S)、40%糖蜜添加组(40S)4个组进行养殖实验,实验周期60 d,每7 d进行一次水质指标检测。运用Biolog-ECO法探究养殖水体微生物代谢多样性。实验结果显示：添加低剂量糖蜜可以有效降低罗非鱼养殖水体中无机氮的含量,对不同形态氮的去除率NO^-₃-N>NO^-₂-N>NH₃-N且实验组平均去除率显著高于对照组。通过Biolog微平板分析养殖水体微生物群落对31种碳源利用能力,AWCD值结果表明不同微生物对碳源的利用能力随时间增加而增加;低剂量糖蜜添加组的微生物活性明显高于对照组。进行主成分分析后发现微生物群落主要利用的碳源类型为氨基酸类、酯类和酸类。低剂量糖蜜添加组与对照组间微生物群落碳源代谢差异...     

饲料中添加中性蛋白酶对吉富罗非鱼生长和消化功能的影响

在吉富罗非鱼(Oreochromis niloticus)基础饲料中添加中性蛋白酶,添加量分别为0.00%、0.05%、0.1%、0.15%、0.2%和0.25%,研究添加后对吉富罗非鱼生长和消化功能的影响。结果表明,在饲料中添加0.1%~0.25%的中性蛋白酶,吉富罗非鱼的相对增重率和特定生长率显著提高,饲料系数显著降低(P<0.05);添加0.1%~0.2%的中性蛋白酶,显著提高饲料干物质表观消化率和粗蛋白表观消化率(P<0.05);添加量为0.1%~0.15%时,肝胰脏蛋白酶显著高于对照组(P<0.05),添加量为0.15%时,肠道蛋白酶活性显著提高(P<0.05)。综合鱼体相对增重率、特定生长率、饲料系数、消化器官消化酶活性等各项指标,吉富罗非鱼饲料中中性蛋白酶的添加量以饲料的0.1%~0.2%为宜。     

吉富罗非鱼对饲料亚油酸的需要量

选用初始体重为(60.98±3.82)g的吉富罗非鱼(Oreochromis niloticus)630尾,随机分成7组(每组设3个重复,每个重复30尾),饲喂亚油酸含量分别为0.07%(对照组)、0.36%、0.61%、1.03%、2.00%、3.00%和4.15%的7种半纯化等能等氮饲料10周。结果表明,鱼体增重率、饲料效率、蛋白质效率和蛋白质沉积率均在亚油酸水平为1.03%时较对照组差异显著(P0.05),且均在饲料亚油酸水平为2.00%时达到最大。经二次回归分析,饲料亚油酸水平为2.49%和2.66%时吉富罗非鱼分别获得最大增重率和最高饲料效率。通过折线回归发现饲料亚油酸水平为1.02%时,吉富罗非鱼获得最大蛋白沉积。肝体比和脏体比均随亚油酸水平的升高而升高,当饲料亚油酸含量为0.61%~4.15%时显著高于对照组(P0.05)。亚油酸添加组的肌肉粗脂肪含量显著高于对照组(P0.05);当饲料亚油酸含量为1.03%~4.15%时,肝和全鱼粗脂肪含量显著高于对照组(P0.05)。随饲料亚油酸水平升高,血清甘油三酯和总胆固醇变化趋势一致,呈现先下降后上升的趋势,经二次回归分析亚油酸水平为1.63%时血清甘油三酯含量最低;各亚油酸添加组的血清高密度脂蛋白胆固醇含量显著高于对照组,且在饲料亚油酸含量为1.13%时达到最大(P0.05);当饲料亚油酸水平为1.03%~4.15%时,血清低密度脂蛋白胆固醇含量显著低于对照组(P0.05)。随饲料中饱和脂肪酸(∑SFA)含量下降,吉富罗非鱼肌肉和肝脏∑SFA含量均呈下降的趋势;随饲料亚油酸水平增加,肌肉和肝脏的n-6多不饱和脂肪酸(∑n-6 PUFA)含量呈上升趋势,肌肉和肝脏的∑n-3 PUFA含量呈下降趋势。综上所述,初始体重为(60.98±3.82)g的吉富罗非鱼饲料亚油酸需要量为1.02%~2.66%。     

吉富罗非鱼成鱼胆碱的最适需要量

选用初始体质量为(220.00±8.34) g的吉富罗非鱼(Oreochromis niloticus)360尾, 随机分成6组,每组3重复(每重复20尾), 于1 m×1 m×1.5 m池塘网箱中饲养。分别饲喂胆碱含量为97.80(对照组)、375.04、565.74、974.27、      1 409.81、1 824.35 mg/kg的半纯化饲料10周, 研究胆碱对吉富罗非鱼成鱼生长、饲料利用、鱼体营养组成、胆碱蓄积量及部分血液生化指标的影响。结果显示, 经过10周的饲喂, 饲料中添加胆碱可显著提高鱼体增重率、特定生长率和饲料效率(P<0.05); 降低肝脂肪含量(P<0.05), 提高肌肉脂肪含量(P<0.05); 显著升高肝胆碱蓄积量(P<0.05); 胆碱添加组血清甘油三酯(TG)和总胆固醇(T-CHO)显著高于对照组(P<0.05), 并随饲料胆碱含量增加呈现升高的趋势; 肝甘油三酯(TG)和总胆固醇(T-CHO)随着胆碱含量的增加而显著降低(P<0.05); 血清谷草转氨酶(ALT)、谷丙转氨酶(AST)和碱性磷酸酶(ALP)均随着饲料胆碱含量的增大而显著降低(P<0.05)。结果表明, 饲料中添加适量的胆碱可以改善吉富罗非鱼成鱼的生长性能, 提高饲料利用效率, 降低肝脂肪含量, 促进肝脂肪转运; 对特定生长率进行回归分析, 得出吉富罗非鱼成鱼对饲料中胆碱的最低需要量为506.43 mg/kg, 而对肝胆碱蓄积量回归分析得出的需要量为981.38 mg/kg。

     

Dietary vitamin C requirement of genetically improved farmed Tilapia,Oreochromis Niloticus

A 12‐week growth experiment was conducted to quantify the appropriate dietary vitamin C requirement for GIFT tilapia Oreochromis niloticus. Triplicate groups of 25 experimental tilapia [initial body weight: (70.0 ± 1.6) g] were cultured in 5.6‐m³ aquaria (r = 1.5 m,h = 0.8 m) and fed with semi‐purified diets containing six levels [6.1 (un‐supplemented diet], 23.8, 41.9, 85.1, 167.4 and 339.0 mg kg^?1 diet respectively) of vitamin C (supplied as L‐ascorbyl‐2‐polyphosphate). The results showed that, increasing dietary vitamin C level up to 41.9 mg kg^?1 diet increased weight gain rate of tilapia, beyond which it remained nearly unchanged. Vitamin C contents in liver and muscle presented first increased linearly then tended to reach saturation at high vitamin C (167.4 and 339.0 mg kg^?1) treatments. Muscle collagen content significantly increased with increasing dietary vitamin C levels. Whole‐body lipid content significantly increased, whereas ash content significantly declined, but moisture and crude protein content showed no significant difference with the increasing of dietary vitamin C. The blood chemistry analysis showed that dietary vitamin C had significant effects on enzyme activities of serum alkaline phosphatase, aspartate aminotransferase and alanine aminotransferase. Significant effects were also observed on albumin and total protein content of serum, but haemoglobin content showed no significant differences among all the treatments. The vitamin C requirement for GIFT tilapia was estimated to be 45.0 mg kg^?1 diet based on maximum growth, 114.9 and 118.6 mg kg^?1 diet based on maximum liver and muscle vitamin C concentration respectively.     

吉富罗非鱼亮氨酸需求量研究

实验以初始体质量为(53.65±0.05)g的吉富罗非鱼幼鱼为研究对象,随机分为7个处理组(每个处理3个重复,每个重复14尾鱼),分别饲喂亮氨酸(Leu)水平为1.11%、1.51%、1.90%、2.29%、2.69%、3.08%和3.48%的7种等氮等能(粗蛋白32%)的半精制饲料56 d,旨在评价吉富罗非鱼对Leu的最适需求量。结果表明,以增重率(WGR)、特定生长率(SGR)、饲料系数(FCR)为评价指标,通过二次回归分析可知,在投饲率为4%~6%时,罗非鱼饲料中适宜的Leu为2.28%~2.33%。随饲料Leu水平的增加,罗非鱼全鱼粗蛋白和粗脂肪、肌肉粗蛋白和粗脂肪均呈先升后降的趋势,而全鱼和肌肉水分差异不显著。罗非鱼胃蛋白酶、肠蛋白酶、肠脂肪酶、肠淀粉酶和Na+-K+-ATP酶的活性也随饲料Leu水平的升高呈先升后降趋势,除肠脂肪酶活性在2.69%水平组最高外,其他指标均在2.29%水平组达到最大值。同时,罗非鱼肠道表皮生长因子(EGF)、肠道表皮生长因子受体(EGFR)、血清超氧化物歧化酶(SOD)、血清溶菌酶(LZM)和血清碱性磷酸酶(AKP)也均在Leu为2.29%水平组达到最大值。研究表明,罗非鱼(50~200 g)饲料Leu的最适需求量为2.28%~2.33%(占饲料蛋白的7.11%~7.26%),该Leu水平能显著促进肠粘膜的发育,增强胃肠消化、吸收能力和机体非特异性免疫能力,从而促进罗非鱼的生长和饲料的转化。     

Comparative digestion efficiencies in conventional, genetically improved and genetically male Nile tilapia, Oreochromis niloticus (L.)

Apparent digestibility of dry matter, protein, lipid and energy of a fishmeal‐based feed (41% crude protein, 9% crude lipid and 19 kJ g⁻¹ gross energy) was compared in genetically improved farmed tilapia (GIFT), genetically male Nile tilapia (GMNT) and conventional Nile tilapia (CNT) (Oreochromis niloticus). The experimental fish were reared individually under standardized conditions in a recirculation system at 27±0.1°C for 10 weeks. Titanium dioxide (TiO₂) was used as a marker. Faeces of individual fish were collected daily by siphoning and stored at −18°C before analysis. No significant differences (P<0.05) were observed in the digestibility coefficients of feed dry matter (78.2±3.4%, 77.7±4.4% and 76.4±3.7%), protein (87.9±3.0%, 88.4±2.8% and 88.0±3.3%), lipid (90.0±2.5%, 91.0±2.1% and 89.4±3.0%) and energy (90.4±1.9%, 90.7±2.0% and 89.4±2.3%) in GIFT, GMNT and CNT respectively. At the end of the experiment, there were no significant differences (P<0.05) in average percentage growth (82.2±7.2, 87.3±7.7 and 74.7±4.1 respectively for GIFT, GMNT and CNT), growth rates or feed utilization efficiencies between the three tilapia groups. We conclude that the higher growth claimed for improved GIFT and GMNT as compared with CNT, if ever existing, cannot be attributed to higher nutrients or energy digestibility.     

Dietary vitamin E requirement of sub‐adult genetically improved farmed tilapia strain of Nile tilapia (Oreochromis niloticus) reared in freshwater

A two‐factor orthogonal test was conducted to determine the dietary vitamin E (VE, dl ‐α‐tocopheryl acetate) requirement for sub‐adult GIFT strain of Nile tilapia (Oreochromis niloticus) at two lipid levels, and evaluate its effect on antioxidant responses. A basal diet containing 60 or 130 g/kg of soybean oil was supplemented with 0, 20, 40, 60, 120 and 240 mg VE/kg, respectively. Each diet was fed to three replicate groups of tilapia with initial weight (80.3 ± 0.7) g for 10 weeks. Results showed that the weight gain, feed efficiency and hepatic VE retention of fish were significantly increased by the increased VE in diets. In groups with 60 and 130 g/kg lipid, fish fed diets supplemented with VE had higher serum superoxide dismutase (SOD) and catalase activity, and lower malondialdehyde content than fish fed the VE un‐supplemented diet (p < .05). The proximate composition of fish had no significant difference in the group with 130 g/kg lipid, whereas crude lipid and ash content were significantly affected by dietary VE in the group with 60 g/kg lipid. Based on broken‐line regression analysis, dietary VE requirement to support the maximum weight gain and serum SOD were 43.2–45.8 and 66.0–76.1 mg/kg in diets with 60 and 130 g/kg lipid, respectively.     

Dietary leucine requirement of Juvenile Nile tilapia,Oreochromis niloticus

An 8‐week feeding trial was conducted to evaluate the effects of dietary leucine on growth performance, feed utilization, body composition and non‐specific immune responses of juvenile Nile tilapia. Five isonitrogenous and isoenergetic diets were formulated to contain graded levels of L‐leucine (5.3, 8.1, 10.9, 13.2, 15.6 and 18.1 g kg^?1 diet, respectively) from dietary ingredients and crystalline L‐leucine. Each diet was randomly assigned to triplicate groups of 20 juvenile fish (1.94 ± 0.01 g) three times daily to apparent satiation. Results showed that the weight gain (WG) and specific growth rate (SGR) increased as dietary leucine concentrations increased from 5.3 to 13.2 g kg^?1 and then decreased slightly with further increase in dietary leucine concentrations. Quadratic regression analysis (y = ?522.6x² + 1304.x + 132.6, R² = 0.684) on weight gain against dietary leucine levels indicated that the optimal dietary leucine requirement was estimated to be 12.5 g kg^?1 diet (corresponding to 43.1 g kg^?1 of dietary protein). Leucine supplementation had no impact on the survival and body composition of tilapia. Serum lysozyme activity of fish fed diet containing 13.2 g kg^?1 leucine significantly increased compared to fish fed diet containing 5.3 g kg^?1. Serum superoxide dismutase activity and immunoglobulin M (IgM) concentration were not significantly affected by dietary leucine supplementation.     

Effect of dietary conjugated linoleic acid levels on growth performance,muscle fatty acid profile,hepatic intermediary metabolism and antioxidant responses in genetically improved farmed Tilapia strain of Nile tilapia Oreochromis niloticus

An 8‐week feeding trial was conducted to determine the effect of dietary conjugated linoleic acid (CLA) on growth performance, muscle fatty acid profile, hepatic intermediary metabolism and antioxidant responses in genetically improved farmed Tilapia (GIFT) strain of Oreochromis niloticus (initial body weight: 42.6 ± 0.4 g, mean ± standard deviation). Three replicated groups of GIFT strain of Nile tilapia were hand‐fed to satiation, twice a day, with the diets in which CLA oil, containing mainly the bioactive cis‐9, trans‐11 and trans‐10, cis‐12 isomers, was included at 0 (control), 0.5%, 1%, 1.5%, 2% and 2.5%, respectively, at the expense of fish oil to maintain the constant lipid and energy levels. Growth performance and feed utilization showed no significant differences among the treatments (P > 0.05). The dietary inclusion of CLA modified total percentages of the main groups of fatty acids. Increasing saturated fatty acid content and reduced mono‐unsaturated fatty acid contents in muscle were observed with increasing dietary CLA inclusion (P < 0.05). Total n‐3 fatty acids and total polyunsaturated fatty acids tended to decline with increasing dietary CLA levels (P < 0.05), but n‐6 fatty acids showed no significant differences among the treatments (P > 0.05). Dietary CLA supplementation resulted in the significant increase in the trans‐10, cis‐12 and cis‐9, trans‐11 CLA isomers in muscle (P < 0.05) and also significantly influenced several hepatic enzymatic activities, such as succinate dehydrogenase, lactate dehydrogenase, malic dehydrogenase, lipoprotein lipase and hepatic lipase activities (P < 0.05). Reduced superoxide dismutase and glutathione peroxidase activities, and the decline in malondialdehyde levels were observed in fish fed the CLA‐supplemented diets (P < 0.05), indicating that dietary CLA supplementation showed a powerful antioxidant effect for this fish species. Our study was the first report involved in the effect of dietary CLA inclusion on hepatic intermediary metabolism and antioxidant responses in fish, which could be used as indicators of nutritional and physiological status of the fish species.