谷氨酰胺对半滑舌鳎稚鱼非特异性免疫相关酶活力和低氧应激后HIF-1表达的影响

为探讨饲料中谷氨酰胺对半滑舌鳎稚鱼非特异性免疫以及低氧应激后HIF-1表达的影响, 实验共设计了4种谷氨酰胺添加量分别为0、0.5%、1.0%和2.0%的等氮等脂微颗粒饲料(游离谷氨酰胺测定值分别为0.03%、0.46%、0.91% 和1.73%), 饲喂35日龄半滑舌鳎稚鱼[平均干重(10.640.86) mg]。每天饱食投喂5次,养殖周期30d, 养殖结束后进行低氧应激实验。研究结果表明, 谷氨酰胺添加量为0.5%时半滑舌鳎稚鱼鱼体溶菌酶(LZM)活力显著高于未添加组(P0.05)。饲料中不同谷氨酰胺水平对鱼体总一氧化氮合酶(TNOS)活力和诱导型一氧化氮合酶(iNOS)活力没有显著影响(P0.05)。实验克隆了半滑舌鳎低氧应激关键基因缺氧诱导因子1 (HIF-1), 得到749 bp半滑舌鳎HIF-1核心序列, 系统进化树分析表明半滑舌鳎HIF-1氨基酸序列与大部分鱼类具有较高同源性。定量PCR结果显示, 饲料中谷氨酰胺水平对低氧应激后半滑舌鳎稚鱼内脏团HIF-1表达量未产生显著影响(P0.05)。综上所述, 在饲料中添加谷氨酰胺能够显著增强半滑舌鳎稚鱼鱼体溶菌酶活力(P0.05), 提高非特异性免疫水平。     

微颗粒饲料中添加精胺对半滑舌鳎稚鱼生长和肠道发育的影响

为获知微颗粒饲料中添加精胺对半滑舌鳎仔稚鱼肠道发育的影响,试验以添加0,0.10%,0.33%精胺的微颗粒饲料（F1、F2、F3）和活饵料卤虫（F4）饲喂初始体长为2 cm左右的半滑舌鳎稚鱼。养殖28d后结果表明,卤虫组（F4）的特定生长率最高,饲料组中F2组特定生长率要显著高于F1和F3组（P0.05）。F3组的存活率仅为60.27%,显著低于其他各组（P0.05）。消化酶活力测定结果中,F2组在14d和28d时都含有较高的碱性磷酸酶比活力和亮氨酸氨基肽酶比活力,较低的亮氨酸-丙氨酸肽酶比活力。卤虫组的肠道发育情况最好,微绒毛长度显著大于其他各组（P0.05）;黏膜厚度略小于F2组,但是没有显著性差异（P0.05）;饲料组中F2组微绒毛长度和黏膜厚度都显著大于F1和F3组（P0.05）。研究表明,在微颗粒饲料中添加0.10%的精胺（F2组）对半滑舌鳎稚鱼肠道发育有促进作用。       

大黄鱼稚鱼L-蛋氨酸需要量的研究

研究了1242日龄大黄鱼（Pseudosciaena crocea R.）稚鱼蛋氨酸需要量。以白鱼粉、磷虾粉和乌贼粉作蛋白源,通过添加L-晶体氨基酸使饲料与大黄鱼卵的必需氨基酸组成一致（蛋氨酸除外）,制成6种等氮（8.8%）等能（16.65 kJ/g）的微黏合饲料。L-蛋氨酸梯度依次为饲料的1.19%、1.62%、2.18%、2.65%、3.13%和3.66%,或饲料蛋白的2.17%、2.95%、3.95%、4.81%、5.70%和6.65%。以生物饵料（丰年虫无节幼体和桡足类）作对照组。每处理设3个重复,每桶（180 L）内随机放3500尾初始体重为（1.930.11） mg 的12日龄大黄鱼稚鱼。实验为期30d。结果显示,稚鱼的成活率随饲料蛋氨酸水平的升高而升高,在2.18%蛋氨酸水平时达到最高,之后无显著变化。特定生长率（SGR）随饲料蛋氨酸水平的升高而升高,在2.18%蛋氨酸水平时达到最高,之后则呈下降趋势。对照组稚鱼的成活率和SGR最高,均显著高于蛋氨酸组（P0.05）。各组间稚鱼体脂肪和灰分差异不显著,但体蛋白随饲料蛋氨酸水平的升高而升高,在2.65%蛋氨酸水平时达到最高,之后则稍微下降;对照组鱼体蛋白和各必需氨基酸含量均显著高于其他组（P0.05）。经二次多项式模型分析,1242日龄大黄鱼稚鱼的蛋氨酸需要量为饲料的2.58%或饲料蛋白的4.69%。       

饲料中添加水解鱼蛋白对半滑舌鳎稚鱼生长及生理生化指标的影响

试验研究了饲料中添加不同水平(0%、20%、40%和60%)的水解鱼蛋白(Fish potein hdrolysate,FPH)对半滑舌鳎(Cynoglossus semilaevis Günther)稚鱼生长及生理生化指标的影响。28d饲养实验结束后,对试验鱼生长指标、鱼体消化酶活性、碱性磷酸酶(AKP)及肠道发育情况进行分析。结果显示:实验鱼的存活率为64.44%—78.88%,其中20%与40%添加组存活率显著高于其他两组(P0.05);实验鱼的特定生长率(SGR)随饲料中FPH添加水平升高呈下降趋势,20%添加组特定生长率最高,显著高于其他3组(P0.05),且60%添加组与对照组(FM)之间无显著差异(P0.05);各试验组鱼体消化酶(脂肪酶、淀粉酶、胃蛋白酶和胰蛋白酶)的比活力在14d与28d时的强弱关系不一致。鱼体碱性磷酸酶比活力大小依次为:20%组40%组对照组60%组,各组间差异均显著(P0.05);半滑舌鳎肠道微绒毛长度和黏膜厚度均以20%添加组为最优,显著优于其他3组(P0.05)。以上结果表明,在实验条件下,饲料中FPH的添加水平为20%时,能提高半滑舌鳎稚鱼的存活率及生长性能,并增强其对营养物质的吸收能力。     

饲料中不同水平鱼蛋白水解物对军曹鱼稚鱼生长及体组成的影响

设计4种等能等氮试验饲料,对照组以鱼粉为单一蛋白源,处理组分别以鱼蛋白水解物替代鱼粉蛋白的17%、34%和51%,军曹鱼(Rachycentron canadum)稚鱼的初始重为(3.79±0.22)g,实验在室内流水养殖系统中进行6周的饲养试验,每种饲料随机3个重复。试验结果显示不同水平鱼蛋白水解物对试验鱼的存活率没有显著影响(P>0.05),除了以鱼蛋白水解物替代鱼粉蛋白51%组外,其他各组的增重率(WG)和饲料摄入量(FI)都是随着饲料中鱼蛋白水解物替代鱼粉蛋白量的增加而增加。试验结果表明,在军曹鱼稚鱼饲料中用鱼蛋白水解物替代34%的鱼粉蛋白对于军曹鱼稚鱼的生长和饲料摄入量具有一定的促进作用。军曹鱼稚鱼血浆中胆固醇含量随着饲料中鱼蛋白水解物添加水平的升高而升高,而血浆中的总蛋白含量则无此规律,各处理组血浆中的甘油三酯无显著差异(P0.05)。       

鸡肉粉完全替代鱼粉饲料中补充包被氨基酸对凡纳滨对虾生长、体成分及组织氨基酸含量的影响

为了探讨鸡肉粉完全替代鱼粉时饲料氨基酸的平衡性以及外源氨基酸的添加方式与凡纳滨对虾生长、体成分、血浆游离氨基酸及肌肉氨基酸含量的关系, 本试验采用26因子试验设计进行了为期56d的饲养试验。2个饲料蛋白质水平分别为40%和32%, 6个饲料处理分别为鱼粉组(对照组)、鸡肉粉组、鸡肉粉+晶体EAA组、鸡肉粉+晶体EAA+晶体NEAA组、鸡肉粉+包被EAA组、鸡肉粉+包被EAA+包被NEAA组, 配制12组饲料。将凡纳滨对虾(0.300.01) g随机分配到36个圆桶(150 L)中, 每桶30尾, 每3个桶为一个处理组, 饲喂一种饲料, 每天饱食投喂三次。在每一饲料蛋白质水平下, 无论是补充晶体氨基酸(CAA)组还是包被氨基酸组对虾的增重率均显著高于鸡肉粉组(P0.05), 且在32%蛋白质水平下, 包被EAA组对虾增重率达到了鱼粉组水平(P0.05); 补充晶体EAA+NEAA组对虾增重率与补充晶体EAA组无差异(P0.05), 但均显著低于补充包被氨基酸组(P0.05); 补充包被EAA组对虾增重率显著高于补充包被EAA+NEAA组(P0.05)。饲料系数的变化正好与增重率变化相反(P0.05)。饲喂高蛋白质水平饲料较之饲喂低蛋白质饲料明显提高对虾增重率、虾体蛋白含量(P0.05), 但降低虾体脂肪含量(P0.05)。包被氨基酸组凡纳滨对虾血浆游离氨基酸含量总体显著低于CAA组(P0.05)。除谷氨酸、甘氨酸以及脯氨酸外, 各组对虾肌肉氨基酸含量无显著差异(P0.05)。结果表明, 在32%饲料蛋白质水平下, 用鸡肉粉完全替代鱼粉时, 饲料中补充包被EAA可明显促进凡纳滨对虾的生长, 且达到了鱼粉组的饲喂效果。     

螺旋藻粉替代饲料中鱼粉对异育银鲫幼鱼生长、饲料利用和蛋白沉积的影响

实验以异育银鲫中科3号幼鱼(3.20.5) g为实验对象, 研究螺旋藻粉蛋白替代饲料鱼粉蛋白(0、20%、40%、60%、80%和100%)对鱼摄食、生长、饲料利用和蛋白沉积的影响。实验设计了6种等氮(38%)等脂(10%)等能(16.50 kJ)的饲料, 每处理3个重复。采用室内循环水养殖系统, 表观饱食投喂。实验水温为(283)℃, 实验共持续60d。结果发现:随藻粉替代比例的增加, 鱼摄食率显著上升; 饲料效率则呈显著下降趋势; 特定生长率在20%替代组与鱼粉组无显著差异(P0.05), 其他各替代组均显著低于鱼粉组(P0.05); 蛋白沉积率在20%、60%替代时与鱼粉组无显著差异(P0.05), 其他替代组显著低于鱼粉组(P0.05); 肥满度在各替代组均显著低于鱼粉组(P0.05); 鱼体蛋白随藻粉替代比例的增加呈现先持平后降低的趋势, 鱼体脂肪则呈先降低后升高的变化; 20%、40%和60%替代组全鱼灰分均高于全鱼粉组; 肠道消化酶(胰蛋白酶、脂肪酶和-淀粉酶)在替代组和对照组间均无显著差异(P0.05); 干物质表观消化率随藻粉蛋白替代比例的增加而呈显著上升, 蛋白的表观消化率则呈显著下降趋势, 总磷表观消化率在20%替代时最低, 在100%替代时最高。综合特定生长率和蛋白沉积率情况, 当鲫幼鱼饲料中鱼粉含量约为50%, 且鱼粉为唯一蛋白源时, 螺旋藻粉蛋白可替代饲料中20%鱼粉蛋白。     

罗非鱼对晶体蛋氨酸、包膜蛋氨酸利用的比较研究

为比较罗非鱼对晶体蛋氨酸、包膜蛋氨酸的利用效果, 设计了鱼粉含量为9%的鱼粉饲料、鱼粉含量为0%的无鱼粉饲料(以豆粕等蛋白替代鱼粉), 在无鱼粉饲料基础上分别添加晶体蛋氨酸、包膜蛋氨酸, 使其蛋氨酸含量与鱼粉饲料一致, 共4种饲料, 饲喂平均体重为(1.220.07) g/尾的奥尼罗非鱼(Oreochromis niloticus O. aureus) 8周。结果表明, 各组罗非鱼增重率分别为1642.7%、1250.3%、1362.0%、1451.7%, 饲料系数分别为1.08、1.45、1.30、1.21; 在无鱼粉饲料中添加晶体蛋氨酸、包膜蛋氨酸提高增重率8.9%、16.1% (P0.05), 降低饲料系数10.34%、16.55% (P0.05); 包膜蛋氨酸组较晶体蛋氨酸组具有更高增重率和更低饲料系数(P0.05)。对摄食后不同时间点肝脏和血浆谷草转氨酶(GOT)、谷丙转氨酶(GPT)活性变化的测定表明, 鱼粉饲料组、无鱼粉饲料组肝脏GOT、GPT活性分别在摄食后第2、第4h出现高峰; 晶体蛋氨酸组在摄食后1h出现高峰, 较无鱼粉组提前; 包膜蛋氨酸组在摄食后第5h出现高峰, 较无鱼粉组滞后; 血浆GOT、GPT活性变化趋势与肝脏的基本一致。消化率试验表明, 鱼粉饲料组干物质、粗蛋白质消化率最高, 无鱼粉饲料组最低; 在无鱼粉饲料中添加晶体蛋氨酸、包膜蛋氨酸后, 干物质、粗蛋白质消化率均得到显著提高(P0.05)。上述结果表明, 在蛋氨酸缺乏的实用饲料中补充晶体或包膜蛋氨酸, 均可显著提高罗非鱼生长性能和营养物质消化率, 包膜蛋氨酸较晶体蛋氨酸具有更高的利用效率和更好的促生长效果。       

饲料中添加水解鱼蛋白对半滑舌鳎稚鱼生长及生理生化指标的影响北大核心

试验研究了饲料中添加不同水平(0%、20%、40%和60%)的水解鱼蛋白(Fish potein hdrolysate,FPH)对半滑舌鳎(Cynoglossus semilaevis Günther)稚鱼生长及生理生化指标的影响。28d饲养实验结束后,对试验鱼生长指标、鱼体消化酶活性、碱性磷酸酶(AKP)及肠道发育情况进行分析。结果显示:实验鱼的存活率为64.44%—78.88%,其中20%与40%添加组存活率显著高于其他两组(P<0.05);实验鱼的特定生长率(SGR)随饲料中FPH添加水平升高呈下降趋势,20%添加组特定生长率最高,显著高于其他3组(P<0.05),且60%添加组与对照组(FM)之间无显著差异(P>0.05);各试验组鱼体消化酶(脂肪酶、淀粉酶、胃蛋白酶和胰蛋白酶)的比活力在14d与28d时的强弱关系不一致。鱼体碱性磷酸酶比活力大小依次为:20%组>40%组>对照组>60%组,各组间差异均显著(P<0.05);半滑舌鳎肠道微绒毛长度和黏膜厚度均以20%添加组为最优,显著优于其他3组(P<0.05)。以上结果表明,在实验条件下,饲料中FPH的添加水平为20%时,能提高半滑舌鳎稚鱼的存活率及生长性能,并增强其对营养物质的吸收能力。     

饲料中棉粕替代鱼粉蛋白对草鱼的生长、血液生理指标和鱼体组成的影响

以初始体重（100.00.29） g的草鱼为研究对象,通过8周的生长实验,研究饲料中棉粕替代鱼粉蛋白对草鱼的生长、饲料利用,血液生理指标和鱼体生化组成的影响。实验设置7种等氮等能饲料,对照组（C）以鱼粉为唯一蛋白源,其余6组分别以棉粕替代饲料中鱼粉蛋白的20% （R20）、40% （R40）、60% （R60）、80% （R80）、90% （R90）、100% （R100）。研究结果表明:随着饲料中棉粕含量的升高,草鱼特定生长率呈下降的趋势,当替代比例达到60%,显著低于对照组（P0.05）;饲料效率、蛋白质贮积率和能量贮积率随着饲料中棉粕含量升高而显著降低（P0.05）。通过折线法分析,在实验条件下,棉粕可以替代鱼粉蛋白的43.3%而不影响草鱼的生长。各组草鱼之间血清谷丙转氨酶、谷草转氨酶和甘油三酯含量无显著差异（P0.05）;总胆固醇、高密脂蛋白胆固醇和低密胆固醇呈现下降趋势,当替代水平达到40%显著低于对照组（P0.05）。棉粕替代鱼粉蛋白显著影响鱼体的水分含量（P0.05）,当替代比例达到80%,鱼体的水分含量显著高于对照组（P0.05）;各组之间鱼体的蛋白质和灰分含量无显著性差异（P0.05）。R20组的鱼体脂肪和能量含量显著高于对照组（P0.05）,R100组的鱼体脂肪和能量含量显著低于对照组（P0.05）,其他各组之间和对照组无显著性差异（P0.05）。       

玉米蛋白粉替代鱼粉对大黄鱼生长、血清生化指标及肝脏组织学的影响

为探讨玉米蛋白粉替代鱼粉对大黄鱼(Larimichthys crocea) 幼鱼生长、血清生化指标及肝脏组织形态的影响, 进行了为期56d的养殖试验, 探索玉米蛋白粉替代大黄鱼幼鱼饲料鱼粉的适当比例。以初始体重为(10.49±0.03) g的大黄鱼幼鱼为研究对象, 用玉米蛋白粉替代基础饲料(含40%鱼粉)0、15%、30%、45%、60%和75%的鱼粉来配制6种等氮(粗蛋白含量45%)等脂(粗脂肪含量10%)的实验饲料, 分别标记为C0、C15、C30、C45、C60、C75组。除C0以外的替代组分别添加了适量的晶体氨基酸(赖氨酸和蛋氨酸)。结果表明, 玉米蛋白粉替代水平对大黄鱼幼鱼存活率、试验鱼特定生长率、饲料系数均无显著性差异(P>0.05)。C45和C60组肌肉粗蛋白含量显著高于C0组(P<0.05), 肌肉粗脂肪含量C45组显著高于C0、C15和C75组 (P<0.05), C45、C60和C75组肌肉水分显著低于C0组(P<0.05), 全鱼粗蛋白、粗脂肪、水分含量无显著差异(P>0.05); 灰分含量有上升趋势, C75组显著高于其他组(P<0.05)。各替代组的血清白蛋白、白球比、谷草转氨酶、葡萄糖均无显著性差异(P>0.05); 随着替代比例的升高, 总胆固醇有降低的趋势, 除C15组与C0无显著性差异外(P>0.05), 4组均显著低于CO组(P<0.05); 实验探讨替代后对鱼的影响, C75组血清总蛋白和球蛋白含量显著低于C0组(P<0.05); C75组血清谷草转氨酶含量显著高于C0(P<0.05)。各处理组总抗氧化能力、过氧化氢酶、谷胱甘肽过氧化氢酶均没有显著性影响(P>0.05), 但替代组总抗氧化能力含量均高于C0; 丙二醛在C75组显著高于C0组(P<0.05)。通过肝组织学观察表明, 当替代比例高于45%时, 呈现肝细胞核偏位、胞浆内脂肪滴较多、细胞透明空泡化等症状。综上所述, 在实验条件下, 研究认为玉米蛋白粉替代鱼粉对大黄鱼幼鱼的适宜添加量为45%。     

Potential use of high levels of vegetal proteins in diets for market-sized gilthead sea bream (Sparus aurata)

The effect of partial or total dietary substitution of fishmeal (FM) by vegetal protein sources on growth and feed efficiency was carried out in on-growing gilthead sea bream (mean initial weight 131 g). The Control diet (FM 100) contained FM as the primary protein source, while in Diets FM 25 and FM 0 the FM protein was replaced at 75% and 100%, respectively, by a vegetable protein mixture consisting of wheat gluten, soybean meal, rapeseed meal and crystalline amino acids. Diets FM 25 and FM 0 also contained krill meal at 47 g/kg in order to improve palatability. At the end of the trial (after 158 d), fish survival was above 90%. Final weight and the specific growth rate were statistically lower in fish fed the Control diet (361 g and 0.64%/d), compared with 390–396 g and 0.69–0.70%/d after feeding vegetal diets. No significant differences were found regarding feed intake and feed conversion ratio. The digestibility of protein and amino acids (determined with chromium oxide as indicator) was similar in all diets. The blood parameters were not significantly affected by treatments. The activity of trypsin and pepsin was significantly reduced after feeding Diet FM 0. In the distal intestine, the villi length in fish fed Diet FM 25 was significantly longer and the intestine of the fish fed the FM 100 diet showed a smaller number of goblet cells. In conclusion, a total FM substitution by a vegetal mix supplemented with synthetic amino acids in on-growing sea bream is feasible.     

Dietary amino acid profiles and growth performance in juvenile kuruma prawn Marsupenaeus japonicus

To assess the reference dietary amino acid profiles for juvenile kuruma prawn Marsupenaeus japonicus a feeding trial was conducted using six semi-purified diets containing casein-gelatin and pre-coated supplemental crystalline amino acids (CAA) and a control diet containing intact protein (casein-gelatin). Pre-coated CAA were supplemented to the diets to simulate dietary amino acid profiles to those of the prawn egg protein (PEP), prawn larvae whole body protein (PLP), prawn juvenile whole body protein (PJP), squid meal protein (SMP), short-necked clam protein (SNP) and brown fish meal protein (BFP). The result showed that kuruma prawn juveniles are capable of utilizing the pre-coated CAA and higher growth performances were observed in the groups fed the PJP, SMP and the control diets than those fed the PLP, SNP, BFP and PEP diets. The essential amino acid proportions (A/E ratios) of the whole body of kuruma prawn differ slightly when compared with the other penaeids or freshwater prawn. The results suggest that PJP and SMP would be suitable as a reference dietary amino acid profile for juvenile prawn.     

Effects of dietary arginine levels on growth performance and body composition of juvenile grouper Epinephelus coioides

An 8‐week feeding trial was conducted to determine the effects of dietary arginine levels on growth performance and body composition of juvenile grouper Epinephelus coioides (initial weight: 16.10 ± 0.26 g per fish) in 500‐L indoor flow‐through circular fiberglass tanks. Diets contained six levels of l ‐arginine ranging from 1.78% to 3.31% of dry diet in 0.30% increments. The diets, in which 25% crude protein came from fishmeal and soybean protein concentrate, and 23% from crystalline amino acids, were formulated to simulate the amino acid profile of 48% whole chicken egg protein except for arginine. Each diet was assigned to three tanks (20 fish per tank) in a completely randomized design. Grouper were fed to apparent satiation (about 5% body weight per day at the initial 1–4 weeks and 3% body weight per day in the following 5–8 weeks) twice daily on weekdays and once daily on weekends. Weight gain (WG) and specific growth rate (SGR) showed an incremental trend with increasing dietary arginine levels from 1.78% to 2.72% and remained thereafter relatively constant. Productive protein value (PPV) was poorest in fish fed the lowest arginine diet (P < 0.05) and showed no significant differences among other treatments (P > 0.05). Dietary arginine contents significantly influenced body composition. With the increase in dietary arginine, contents of total essential amino acids (EAAs), total non‐EAAs and total amino acids of whole body significantly increased (P < 0.05). The retention of dietary EAA in whole body of juvenile grouper was significantly influenced by dietary arginine. Arginine retention increased with increasing dietary arginine levels from 1.78% to 2.72%, then declined above the level of 2.7% (P < 0.05). Based on broken‐line regression analysis of WG against dietary arginine levels, the dietary arginine requirement of juvenile grouper E. coioides was determined as 2.7% of the diet (corresponding to 5.5% of dietary protein).     

异育银鲫幼鱼对饲料苯丙氨酸需求的研究

通过55d的生长实验确定异育银鲫幼鱼对饲料苯丙氨酸的适宜需求。实验结果表明,饲料苯丙氨酸含量为1.09%时,异育银鲫幼鱼的增重率、特定生长率和饲料效率均到达最大值,分别为194.50%、1.96%/d、37.74%,而摄食率为最小值4.76%/d。饲料添加适宜水平的苯丙氨酸也显著提高其蛋白质效率、蛋白质沉积率和能量沉积率,均以1.09%处理组显著高于其他各处理组(P0.05)。根据异育银鲫幼鱼特定生长率与饲料苯丙氨酸水平的剂量效应关系,通过非线性回归可以得出饲料酪氨酸为1.04%时异育银鲫幼鱼的苯丙氨酸最适需求量占饲料1.09%,占饲料蛋白的3.02%。       

异育银鲫幼鱼对饲料中缬氨酸需求量的研究

通过65d的生长实验, 探讨饲料中不同缬氨酸水平对异育银鲫(Carassius auratus gibelio)幼鱼平均体重(3.17±0.01)g/尾生长性能、饲料利用和蛋白利用的影响, 确定异育银鲫对饲料中缬氨酸的需要量。实验设计由酪蛋白、明胶和晶体氨基酸为蛋白源的8种等氮(蛋白含量:38%)等能(总能:17.0 kJ/g)的半精制饲料, 其缬氨酸水平等梯度逐步升高(0.54、0.79、1.04、1.29、1.54、1.79、2.04、2.29%饲料干物质)。各实验饲料中缬氨酸的实测值分别为:0.66、0.85、1.07、1.22、1.46、1.70、1.86和2.12%饲料干物质。饲料中其他必需氨基酸含量参照异育银鲫肌肉氨基酸模式。每种饲料饲喂3个重复,每个重复30尾鱼,养殖于塑料方箱中(70 cm×55 cm×50 cm;水体容积:150 L), 养殖系统为室内流水系统(500 mL/min流速), 每天两次饱食连续投喂(9:00和16:00)。实验结果表明,饲料中适量的缬氨酸显著提高了异育银鲫的特定生长率、饲料转化效率和蛋白沉积率(P0.05), 但显著影响了血清谷氨酰胺的浓度(P0.05), 但不同的缬氨酸水平显著影响了鱼体灰分含量(P<0.05)。对各处理组异育银鲫特定生长率的结果进行二次回归分析, 结果表明满足异育银鲫最大生长的缬氨酸需求量为饲料干物质的1.72%, 即占饲料蛋白的4.53%。       

Inclusion of alternative marine by-products in aquafeeds with different levels of plant-based sources for on-growing gilthead sea bream (Sparus aurata,L.): effects on digestibility,amino acid retention,ammonia excretion and enzyme activity

The search for new sustainable aquafeeds for the species with greater economic importance, such as the gilthead sea bream in Europe, is one of the main challenges in the aquaculture sector. The present work tested fishmeal replacement by a mixture of plant meals at different levels, as well as the use of marine by-products with attractant properties and high-quality protein in high plant protein diets. In order to do that, effects on growth and biometric parameters, digestibility, amino acid retention, excreted ammonia and proteases and amylase activity were assessed, using six different diets: FM100 (100% of protein provided by fishmeal), FM50 (50% of replacement), FM25 (75% of replacement) and FM0 (100% of replacement), but also FM25+ (75% of replacement and 15% of squid and krill meal inclusion), and FM0+ (100% of replacement and 15% of squid and krill meal inclusion). In group FM0, a clear impact of dietary changes was observed on growth, survival and ammonia excretion. Amino acid retention in group FM0+ was also significantly affected, which can be explained by the limited content of certain amino acids in this diet. On the other hand, no significant differences were observed in most biometric parameters or in enzyme activity. In conclusion, complete fishmeal replacement can be achieved by using a mixture of plant-based sources, but supplementation with complementary marine ingredients can prevent detrimental effects on growth, survival, nutritional parameters and protein metabolism.