大口黑鲈北方亚种群体和“优鲈1号”群体及其正反杂交子代的遗传和生长性能比较

为解决国内养殖的大口黑鲈(Micropterus salmoides)群体遗传多样性下降问题,进一步培育快长和抗逆性强的大口黑鲈优良品种,以引进的大口黑鲈北方亚种群体(N)和大口黑鲈"优鲈1号"(G)为亲本,通过自交和正反杂交获得4个大口黑鲈群体,利用12对微卫星引物对其进行遗传多样性及遗传结构分析,采用金属丝线码(CWT)标记后在相同池塘养殖条件下对4个群体的生长性能进行比较分析。结果显示,12对微卫星引物在所有个体中均能扩增出清晰条带,在120尾样本中共扩增到126个等位基因,北方亚种自交群体(N)、"优鲈1号"自交群体(G)、正交群体NG[N(♀)×G(♂)]、反交群体GN[G(♀)×N(♂)]的平均期望杂合度(H_e)分别为0.491、0.454、0.553和0.519,平均观测杂合度(H_o)分别为0.519、0.480、0.729和0.664,平均多态信息含量(PIC)分别为0.407、0.412、0.454和0.425。结果表明,正反交群体的遗传多样性均高于自交群体,其中NG群体的遗传多样性最高。对群体间的遗传分化分析表明,GN群体与N和G群体间遗传分化最大,分别为0.125和0.149。UPGMA聚类分析显示,N群体和G群体首先聚为一支,再与NG群体聚为一支,最后与GN群体聚合。对4个群体的3～12月龄的子代生长性状进行对比,GN群体的体质量绝对增长率(AGR)和特定增长率(SGR)分别为1.44 g·d~(-1)和1.04%·d~(-1),均高于其他群体。研究结果可为今后大口黑鲈良种培育和遗传改良提供科学依据。     

大口黑鲈3个养殖群体的遗传多样性分析

该研究通过毛细管电泳法筛选微卫星引物,从GenBank的51对微卫星引物中共筛选出12对具有特异性和多态性的引物,并合成荧光标记引物,对广东大口黑鲈(Micropterus salmoides)主养区3个养殖群体进行STR分型,以分析其遗传多样性。结果显示所检测的12个微卫星位点中,3个位点呈现高多态性,4个具有中度多态性,其余5个位点为低多态性。3个群体的遗传多样性水平偏低,期望杂合度(He)分别为0.312 5、0.360 6和0.328 4。群体间遗传分化指数及AMOVA分析显示,群体间遗传分化属于低水平,遗传变异有85.83%是由群体内不同个体间的差异造成的。群体间遗传距离分析显示,3个养殖群体间的遗传距离和遗传相似度比较接近。遗传结构分析表明3个养殖群体来自于同一个亚群。研究结果提示现阶段中国大口黑鲈养殖群体的遗传多样性已显著下降,因此在选育种过程应高度重视提高与维持种群遗传多样性的问题。     

大口黑鲈选育群体遗传多样性的AFLP分析

采用AFLP技术对大口黑鲈(Micropterus salmoides)F3、F4代选育群体的遗传结构进行分析,并计算2个选育群体和一个对照养殖群体的遗传多态度、遗传距离及分化系数。结果显示,8对AFLP引物共扩增到262条带,其中多态性条带有80条,每对引物检测到的多态性条带在5～13之间。F3、F4代选育群体和对照养殖群体的多态性位点比例分别为29.36%、29.20%、30.29%。Shannon多样性指数分别为0.2017,0.1955,0.2042。结果表明,选育群体相较于对照养殖群体多态位点比例和遗传多态度均有所下降。群体间的遗传变异平均为0.0752,由此可见,92.48%的遗传变异来自于群体内,而只有7.52%的遗传变异来自于群体间,这初步显示了大口黑鲈在遗传上的稳定性,群体尚具有一定的选育潜力,可继续进行人工选育。     

长江刀鲚选育和野生群体遗传多样性的微卫星分析

利用微卫星标记技术,对长江刀鲚野生群体(YS)与3个连续选育世代群体(F_1、F_2、F_3)间的遗传多样性进行了分析。12对多态性微卫星引物总共检测到等位基因82个,平均每对引物获得等位基因6. 83个。4个群体的平均有效等位基因数(Ne)、平均观测杂合度(Ho)、平均期望杂合度(He)以及平均多态信息含量(PIC)分别为3. 47～4. 10、0. 400 0～0. 516 7、0. 684 4～0. 738 1和0. 646 4～0. 701 2。F_1、F_2、F_3之间的遗传分化微弱(FST0. 05),并与YS具有中等程度的遗传分化(0. 05 F_(ST)0. 15)。分子方差分析(AMOVA)结果显示,大部分的遗传变异来源于个体间(93. 66%),仅有6. 34%的遗传变异来源于群体间。F_1、F_2、F_3的遗传变异水平低于YS,且呈现出伴随着选育世代的进行而降低的趋势,表明选育群体随着人工选育的进行而日趋纯化,但仍然具有丰富的遗传多样性和进一步选育的潜力。     

津鲢与长江鲢遗传多样性分析

随机选取津鲢和长江鲢各36尾,用16个微卫星标记进行遗传多样性分析。结果显示:16个微卫星位点在2个群体中共检测到等位基因105个,基因型241种,每个位点等位基因数3～15个,平均6.6个,基因型4～37种,平均15.1种。2个鲢群体平均观察杂合度(Ho)分别为0.5393和0.5392,平均期望杂合度(He)分别为0.5887和0.5762,结果表明该2个鲢群体遗传多样性水平较高。2个鲢群体平均多态信息含量(PIC)分别为0.5602和0.54,固定系数(FIS)表明这2个鲢群体表现为杂合子缺乏(FIS0)。2个鲢群体之间的遗传距离为0.0566,平均遗传分化系数(Fst)值为0.021,说明仅有2.1%的遗传变异来源于群体间。     

基于SSR-seq技术评估中间球海胆多代选育群体和普通养殖群体的遗传多样性

为明确不同选育群体中间球海胆的遗传多样性和遗传结构,利用SSR-seq技术和15个微卫星位点,对1个家系选育群体(FP)、1个群体选育群体(IP)和1个未经选育的普通养殖群体(CP)的遗传多样性及遗传结构进行了分析。结果显示,15个微卫星位点共检测出112个等位基因,FP、IP、CP 3个群体的平均观测等位基因数(N_a)分别为5.077、5.133和6.133个,平均有效等位基因(N_e)分别为2.816、2.873和3.638个,平均观测杂合度(H_o)分别为0.522、0.441和0.501,平均期望杂合度(H_e)分别为0.595、0.599和0.667,平均多态性信息含量(PIC)分别为0.546、0.543和0.623。家系选育群体(FP) H_e与H_o的差值(0.073)低于IP (0.158)和CP (0.166),平均固定指数(F)(0.115)低于IP (0.248)和CP (0.246)。3个群体间遗传分化系数(F_st)介...     

中华鳖黄河群体选育F3与大陆代表性群体遗传变异的微卫星分析

利用微卫星分子标记技术,对中华鳖(Trionyx sinensis)黄河群体选育F3世代与其基础群体—黄河野生群体以及淮河、鄱阳湖、洞庭湖、太湖野生群体的遗传变异进行了测定和比较分析。结果表明:①从所筛选的14个微卫星位点中,6个群体共检测出334个等位基因;平均等位基因数(N a)为3.6⁴.2,平均有效等位基因数(N e)为2.534.2,平均有效等位基因数(N e)为2.53².99,平均观察杂合度(H o)为0.47142.99,平均观察杂合度(H o)为0.4714⁰.5821,平均期望杂合度(H e)为0.551 50.5821,平均期望杂合度(H e)为0.551 5⁰.599 7,平均多态信息含量(PIC)为0.487 20.599 7,平均多态信息含量(PIC)为0.487 2⁰.540 6,平均Shannon多样性指数(H')为1.0010.540 6,平均Shannon多样性指数(H')为1.001¹.106,表明这6个中华鳖群体均具有较为丰富的遗传多样性。②基于D遗传距离构建的UPGMA聚类树显示,黄河群体选育F3世代与黄河群体聚为一支,鄱阳湖群体与洞庭湖群体聚为一支,淮河群体与太湖群体聚为一支。③群体间F统计量及AMOVA分析表明,黄河群体选育F3世代与黄河群体遗传分化不显著(P>0.05),但与淮河、鄱阳湖、洞庭湖及太湖群体遗传与差异极显著(P<0.01)。④三代选育已使黄河鳖选育群体渐趋纯化,其遗传多样性略低于其它群体,但其F3世代仍保持较高的遗传多样性,显示具有较大的选育潜力。     

吉富罗非鱼不同选育群体的遗传多样性

用微卫星和扩增片段长度多态性(amplified fragment length polymorphism,AFLP)分子标记对海南、广州和青岛吉富品系尼罗罗非鱼的遗传多样性和遗传分化进行了研究。9对微卫星引物和4对AFLP引物的分析结果一致。微卫星分析表明,青岛吉富鱼的平均等位基因数(4.8)、平均观测杂合度(0.528)、平均多态信息含量(0.605)最高,海南吉富鱼的平均等位基因数(4.4)、平均观测杂合度(0.479)、平均多态信息含量(0.549)最低。AFLP分析显示,青岛吉富鱼的多态位点比例(48.4%)和基因多样性(0.245)最高,海南吉富鱼的多态位点比例(36.3%)和基因多样性(0.147)最低。这些表明,青岛吉富鱼的遗传多样性最高,海南吉富鱼最低。遗传分化分析表明,两两群体间遗传分化显著(微卫星FST为0.07~0.11,P<0.01;AFLPFST为0.24~0.29,P<0.01)。AMOVA分析显示,大部分遗传变异(微卫星的分析结果为91.26%;AFLP的为67.6%)来源于群体内个体间,表明吉富鱼选育品系尚具有进一步选育的潜力。     

中华绒螯蟹人工选育群体的遗传多样性

利用10对微卫星引物对中华绒螯蟹(Eriocheir sinensis)长江水系天然群体、人工选育F4A级群体、F4B级群体以及江苏射阳群体共95个体进行遗传多样性分析。F4A、F4B选育起始群体均来源于固城湖国家级长江水系中华绒螯蟹原种场,射阳群体为江苏省河蟹养殖普遍采用的苗种,其亲本为当地养殖河蟹。结果表明,中华绒螯蟹4个群体的平均观察杂合度(H o)分别为0.8053、0.8197、0.8105、0.8100,平均期望杂合度(H e)分别为0.7149、0.7161、0.7262、0.7286。其中,人工选育F4A级以及B级群体的遗传多样性指数均高于天然群体,但是无显著性差异(P0.05)。总体而言,本研究中4个群体的遗传多样性均处在较高水平,其中射阳群体的平均期望杂合度最高,天然群体最低,各群体间遗传多样性亦无显著性差异(P0.05)。聚类分析结果发现,天然群体、F4A级和F4B级选育群体聚为一支,而射阳群体单独聚为一支,表明人工选育中华绒螯蟹群体与长江水系天然群体间没有发生显著性遗传分化。     

大口黑鲈“优鲈3号”

正一、品种名称大口黑鲈"优鲈3号"二、品种来源大口黑鲈"优鲈1号"和2010年美车引进的大口黑鲈北方亚种。三、审定情况2018年12月通过全国水产原种和良种审定委员会审定。审定编号为GS-01-001-2018。四、特征特性1.生长快。在人工配合饲料喂养时一龄大口黑鲈"优鲈3号"生长速度(体重)比大口黑鲈"优鲈1号"平均提高17.1%,比大口黑鲈引进群体提高33.92%～38.82%。2.易驯食。驯化摄食配合饲料的时间缩短,驯食成功率显著提高。     

Digestibility of plant protein-based diets by largemouth bass Micropterus salmoides

Commercial farming of carnivorous fish demands the reduction of environmental impact of feeds; that requires minimal use of dietary animal protein. This study investigated the digestibility of diets formulated exclusively out of plant protein, added feed attractants, by the carnivore largemouth bass, Micropterus salmoides . Juvenile largemouth bass (14.0 ± 1.0 cm) conditioned to accept artificial, dry feed were confined in polypropylene cages and fed ad libitum in three daily meals, seven experimental diets containing varying levels of vegetable and animal protein sources, added of different feed stimulants. After last daily meal, cages were transferred to cylindrical–conical-bottomed, 200-L aquaria, where faeces were collected by sedimentation into refrigerated containers, preserved and later analysed for chemical composition. Soybean meal can be used as partial substitute of animal protein in diets for largemouth bass; the poultry by-product meal shows as a good option as animal protein source in these rations. Control treatment – 50PP : 50AP – yielded best performances; the need for the use of fish meal in the formulation for carnivorous diets is, at least, questionable. Results of the digestibility trials demonstrated the importance of determining the diet digestibility, if precision in the formulation of least-cost feeds for carnivorous fish is the ultimate goal.     

基于线粒体D-loop区探讨我国养殖大口黑鲈的分类地位和遗传变异

对大口黑鲈国内养殖种群(G)和北方亚种(N)、佛罗里达亚种(F)两个野生种群共23个个体的线粒体DNA D-loop区序列进行分析,探讨国内养殖大口黑鲈(Micropterus salmoides)的分类地位和遗传变异。D-loop区序列分析结果表明,共检测到73个变异位点,总变异率为9.0%。三群体间没有共享单倍型,群体G的5个个体含2种单倍型,群体N的11个个体含9种单倍型,群体F中每个个体均为一种单倍型。对三个群体间的遗传距离分析表明,养殖群体与北方亚种野生群体的遗传距离为0.009,与佛罗里达亚种野生群体的遗传距离为0.053,表明国内养殖的大口黑鲈在分类上属于北方亚种,分子系统进化树的进一步分析结果与其一致。群体N、F和G的核苷酸多样性指数(π)依次为0.008 2,0.013和0.000 5,单倍型多样性指数(h)分别为0.946,1.000和0.400,显示出养殖大口黑鲈群体的遗传多样性相比国外野生群体有明显下降,有必要开展大口黑鲈的遗传改良研究,提高其种质质量。     

Diet of the largemouth bass, Micropterus salmoides (Lacepède), in Lake Naivasha, Kenya

Abstract The major food items of adult largemouth bass, Micropterus salmoides (Lacepède), in Lake Naivasha, Kenya are not markedly different from those in its native range. Although insects and their larvae are major components of the diet for both temperate and equatorial populations of juvenile bass, the equatorial population also eats Procambarus clarkii (Girard), juvenile fish and aquatic weeds. In temperate populations they also eat crustaceans, rotifers and oligochaetes. The frequency of occurrence of the major prey organisms in the stomachs of M. salmoides varies seasonally with population peaks in these organisms. Similar to North American populations, the Naivasha population feeds during the day between dawn and dusk. In contrast to temperate populations, the population of M. salmoides in this equatorial lake feeds throughout the year, with feeding intensity correlated with water temperature.     

发酵桑叶替代鱼粉对大口黑鲈生长、脂质代谢与抗氧化能力的影响

在基础饲料中用发酵桑叶分别替代0、15%、30%鱼粉,再对30%鱼粉替代水平饲料补充晶体赖氨酸和蛋氨酸,配制成4种等能等氮(CP 42%,GE 18 MJ/Kg)的实验饲料,分别表示为D_1、D2、D_3和D4,饲喂大口黑鲈(初始体质量10 g)8周,研究发酵桑叶替代鱼粉对大口黑鲈生长、脂质代谢和抗氧化能力的影响。结果显示,发酵桑叶替代30%鱼粉会显著降低大口黑鲈的终末体质量、特定生长率(SGR)、脏体比(VSI)和肝体比(HSI),补充晶体氨基酸(CAA)后会明显改善大口黑鲈的生长性能。各实验组蛋白质效率、饲料系数、摄食率、肥满度以及全鱼常规组成均无显著差异。发酵桑叶替代30%鱼粉会显著降低大口黑鲈血清总胆固醇(CHO)、甘油三酯(TG)、高密度脂蛋白胆固醇(HDL-C)和低密度脂蛋白胆固醇(LDL-C)含量,提高HDL-C/CHO和HDL-C/LDL-C比值。随发酵桑叶替代水平的增加,大口黑鲈血清低密度脂蛋白胆固醇(LDL-C)含量和丙二醛(MDA)含量显著降低,而超氧化物歧化酶(SOD)活性显著升高。研究表明,发酵桑叶替代适宜水平鱼粉不会影响大口黑鲈的生长,而替代鱼粉水平过高会显著抑制大口黑鲈的生长,但可以改善大口黑鲈的脂质代谢和机体抗氧化能力。饲料中补充晶体氨基酸可以提高桑叶的利用率,促进大口黑鲈生长。     

Production performance of largemouth bass Micropterus salmoides and water quality variation in monoculture,polyculture and integrated culture

A 74‐day experiment was conducted to evaluate the production performance and water quality variation in three types of farming system for largemouth bass Micropterus salmoides. The tested aquaculture models included monoculture of largemouth bass (MC), polyculture of largemouth bass, gibel carp Carassius auratus gibelio and silver carp Hypophthalmichthys molitrix (PC), and integrated culture of largemouth bass, gibel carp, silver carp and freshwater pearl mussel Hyriopsis cumingii (IC). The ratio of largemouth bass, gibel carp and silver carp was 30:2:1 in the PC model, and the ratio of largemouth bass, gibel carp, silver carp and mussel was 30:2:1:5 in the IC model. The largemouth bass were fed with formulated feed twice daily. No significant differences were found in weight gain and yield of largemouth bass, total fish yield, nitrogen (N) and phosphorus (P) utilization efficiencies, N and P wastes, pH, nitrite, nitrate, reactive phosphate, total nitrogen, total phosphorus, total organic carbon, chemical oxygen demand, 5‐day biochemical oxygen demand, chlorophyll a, primary productivity among the MC, PC and IC models. The ammonia was lower, while the dissolved oxygen was higher in the PC tanks than in the MC tanks. These results suggest that the environment situation was better in the PC tanks relative to that in the MC tanks. The present study reveals that the PC model should be a way to optimize the aquaculture model for commercial largemouth bass farming.     

Diet of introduced largemouth bass in Korean rivers and potential interactions with native fishes

Abstract –  A dietary analysis of largemouth bass ( Micropterus salmoides ), an exotic, piscivorous species, was conducted in large South Korean river systems (>third order streams, 31 sites). Micropterus salmoides larger than 100 mm exhibited intense piscivory on native Korean juvenile fishes, with levels of piscivory amongst the highest recorded globally, for native and introduced populations. Largemouth bass exhibited an ontogenetic shift in diet, showing a progressive increase in piscivory with size, typical of this species within its native range but unlike several studies on introduced largemouth bass in Europe and Africa. Sampling of fish communities at the same sites used for diet studies showed that native piscivores and the main food fish species of largemouth bass were significantly less abundant ( P  = 0.049 and 0.045, respectively) at sites where bass were present than at sites where no bass were recorded. Largemouth bass may pose a threat to the structure of fish assemblages in Korean river systems and further study of their population interactions and how to minimise their spread is needed.     

大口黑鲈北方亚种和佛罗里达亚种及其杂交子代的遗传分析

用18对微卫星引物对大口黑鲈北方亚种(Micropterus salmoides salmoides,N)、佛罗里达亚种(M.salmoides floridanus,F)及其正交子代(N♀×F♂)和反交子代(F♀×N♂)进行遗传多样性和遗传结构分析。结果表明,18对引物扩增出的等位基因数为2~8个,平均等位基因数为5.0。检测到6对(Jzl48、Jzl68、Jzl84、MiSaTPW76、Msal21、Mdo6和Mdo7)亚种间特异性引物,其中有2对引物(Jzl48和Mdo7)可以用来鉴别大口黑鲈北方亚种、佛罗里达亚种和其杂交子代。平均有效等位基因数、平均期望杂合度和平均多态信息含量均为杂交组合F♀×N♂最高,分别为3.199 7,0.638 9和0.570 6,平均观测杂合度为杂交组合N♀×F♂最高(0.848 8)。对亲代与杂交子代间的遗传分化分析表明,正反交子代均与北方亚种的遗传分化最小(0.092和0.119 6)。基于Nei’s遗传距离构建的UPGMA系统进化树显示正交子代N♀×F♂与母本N聚为一支,反交子代F♀×N♂与父本N聚为一支。     

用微卫星DNA技术对中国对虾人工选育群体遗传多样性的研究

利用微卫星技术对中国对虾人工选育群体第1代和第6代群体的遗传多样性进行了分析。对10个微卫星位点进行了扩增,共产生74个等位基因,每个位点产生的等位基因数从3到13不等。在两个群体中,所观察到的等位基因数都比有效等位基因数多。多态信息含量PIC值0．5567～0．8877,说明这10个微卫星位点在中国对虾中具有较高的信息含量。两个群体的平均杂合度分别为0．6400(CP1)、0．6300(CP6),并通过计算基因型的P值,确定了对Hardy-Weinberg平衡的偏离情况。对Fis值的计算表明两个群体内共有5个微卫星位点存在杂合度观察值过剩的现象。两个群体的Shannon多样性指数分别为1．6830、1．7382,整个选育群体(两个群体作为一个群体)的遗传多样性指数为1．7742。从遗传多样性所占的比例来看,96．415％的遗传变异是来自群体内,只有3．585％的遗传变异是来自群体间。两个群体间的相似性系数高达0．9187,彼此间的遗传距离仅为0．0848,体现出人工选育群体的遗传分化程度较低。结果均说明第6代群体还有较大的选育潜力,可以继续保持遗传效应,最终保证选种育种工作的成功。     

Genetic relationship between broodstocks of olive flounder, Paralichthys olivaceus (Temminck and Schlegel) using microsatellite markers

For the first generation of a selective breeding programme, it is important to minimize the possibility of inbreeding. This mostly occurs by mating between closely related individuals, while proper mating can provide an opportunity to establish the base families with wide genetic variation from which selection for subsequent generations can be more effective. Genotyping with microsatellite‐based DNA markers can help us determine the genetic distances between the base populations. The genetic markers further facilitate the identification of the correct parents of the offspring (parentage assignments) reared together with many other families after hatching. We established a genetic analysis system with microsatellite DNA markers and analysed the genetic distances of three farmed stocks and a group of fish collected from wild populations using eight microsatellite markers. The averaged heterozygosity of the farming stocks was 0.826 and that of the wild population was 0.868. The hatchery strains had an average of 8.6 alleles per marker, which was less than a wild population that carried an average of 14.3 alleles per marker. Significant Hardy–Weinberg disequilibrium (HWDE) was observed in two farming stocks (P<0.05). Despite relatively low inbreeding coefficiency of the hatchery populations, the frequency of a few alleles was highly represented over others. It suggests that the hatchery stocks to some extent have experienced inbreeding or they originated from closely related individuals. We will develop a selective program using the DNA markers and will widen the usage of the DNA‐based genetic analysis system to other fish species.     

以大口黑鲈和大黄鱼配合饲料应用为例谈 改变鱼类营养和饲料研究范式

鱼类营养和饲料研究始于70年前并借鉴陆生动物营养研究经验形成了研究范式。在过去70年中,鱼类营养和饲料研究取得了大量的成果,这些研究成果推动了水产配合饲料技术的进步,为水产饲料产业从无到有、从小到大做出了贡献。然而,随着全球水产养殖规模的不断扩大,水产养殖发展面临的资源和环境压力日益增加,对水产饲料也提出了更高的要求。事实表明,根据一些鱼类营养和饲料研究成果所配方的饲料在养殖生产实践中往往不能取得预期的应用效果,这意味着在已有范式下取得的研究成果有时难以很好地满足现代鱼类养殖产业的需要。本文叙述了具有重要经济价值的两种肉食性鱼类大口黑鲈和大黄鱼配合饲料研发与应用的历程,指出对饲料蛋白需求的低估是限制配合饲料长期未能在大口黑鲈和大黄鱼养殖生产中应用的主要原因。早期研究报道大口黑鲈的饲料蛋白需求为400-440 g/kg,大黄鱼的饲料蛋白需求为450-470 g/kg。经过重新评估后将大口黑鲈和大黄鱼的最适饲料蛋白水平分别提高到480-510 g/kg和490-520 g/kg。在适宜的饲料蛋白水平下,投喂配合饲料的大口黑鲈和大黄鱼生长与投喂冰鲜鱼时相当。作者认为对饲料蛋白需求的低估与已有鱼类营养和饲料研究范式存在的不足有关,其表现为：（1）强调食物对鱼类生长的作用,但忽视了实验鱼遗传背景和食物以外的环境条件对生长和摄食的影响;（2）强调鱼类个体生长对评价营养需求和饲料质量的重要性,但忽视了鱼类个体生长差异并不能完全反映养殖产量和效益的事实;（3）强调生长和饲料利用效率作为鱼类营养和饲料研究评价指标的重要性,但忽视了养殖对环境和自然资源的负面影响是限制水产养殖产业可持续发展的瓶颈;（4）没有足够重视基础饲料配方在评价营养需求或饲料质量方面的影响,一些研究因基础饲料组成不当而产生没有实际意义的评价结果。针对上述问题,作者建议从概念、理论和研究方法方面对已有的范式做如下修改：（1）重视鱼类遗传背景和食物以外的环境条件对鱼类生长的影响,明确鱼类营养需求取决于其生长需求;（2）重视食物中各种营养素之间的相互作用,明确不同饲料原料在实现配方的营养平衡方面发挥着不同的作用;（3）重视对实验鱼种质和种群结构的选择,重视对照组和处理组个体生长差异的幅度对判断饲料处理效应的指示作用,重视饲料配方对渔业资源和环境等水产养殖可持续发展相关的内容的影响。经过修改后的研究范式更符合养殖生产实际,在此基础上开展研究所获得的成果也能够更好地指导配合饲料生产,为鱼类养殖产业的可持续发展提供更好的科技支撑。