江鳕胚后发育的形态观察

对江鳕(Lotalota)出膜后仔鱼各个器官的发育进行了系统观察。结果表明,从形态发育来看,江鳕发育分为仔鱼期和稚鱼期。仔鱼期又分为卵黄囊期仔鱼和后期仔鱼,根据外部形态和发育特点分为11个发育期;卵黄囊期(0～31日龄)仔鱼生长发育缓慢;后期仔鱼期(32～62日龄)生长发育较快。稚鱼期主要是鳞片形成(63～67日龄),所有器官形成历时67d。     

江鳕胚后形态发育特征

在直径2m的圆形玻璃钢槽内,水深0.3m,弱光,水温6～16℃下,详细观察了江鳕（Lota lota Linnaeus）胚后发育过程。结果表明,依形态发育,将出膜后的江鳕发育分为两个阶段（仔鱼期和稚鱼期）11个发育期。仔鱼期分为卵黄囊期仔鱼和后期仔鱼,历时62d;卵黄囊期仔鱼由单独依靠内源营养至混合营养过程,包括孵出期、胸鳍形成期、鳃弧期、鳔形成期和腹鳍形成期,历时31d;后期仔鱼从卵黄囊和油球消失,仔鱼完全依靠外源营养到各鳍基本形成为止,包括卵黄消失期、尾鳍形成期、背鳍分化期和臀鳍形成期,历时31d。稚鱼期包括鳞片出现期和鳞片形成期,历时5d。卵黄囊期仔鱼生长发育缓慢,后期仔鱼期和稚鱼期生长发育较快。     

江鳕胚后形态发育特征

在直径2m的圆形玻璃钢槽内,水深0.3m,弱光,水温6～16℃下,详细观察了江鳕(Lota lota Linnaeus)胚后发育过程.结果表明,依形态发育,将出膜后的江鳕发育分为两个阶段(仔鱼期和稚鱼期)11个发育期.仔鱼期分为卵黄囊期仔鱼和后期仔鱼,历时62d;卵黄囊期仔鱼由单独依靠内源营养至混合营养过程,包括孵出期...     

鞍带石斑鱼仔稚（幼）鱼的发育和生长研究

对鞍带石斑鱼的仔稚幼鱼形态发育的各个阶段进行了观察与研究,详细描述从初孵仔鱼到幼鱼各个发育时期的形态特征和发育时间。根据卵黄囊的变化,长鳍棘的长出与收缩,鳞片和体色斑纹的出现,鞍带石斑鱼胚后发育可以划分为仔鱼期、稚鱼期、幼鱼期。仔鱼期又可分为卵黄囊期仔鱼和后期仔鱼。水温27～30℃,盐度27～31,pH值8.0～8.4的海水中培育,初孵仔鱼至孵化后2日龄为卵黄囊期仔鱼。2日龄仔鱼开口,3日龄至20日龄为后期仔鱼,22日龄至30日龄为稚鱼期,31日龄进入幼鱼期。鞍带石斑鱼胚后发育过程中最明显的变化是背鳍棘和腹鳍棘的生长和收缩,也是生产育苗当中比较关键的仔稚幼鱼变态过程。     

黄斑篮子鱼仔、稚、幼鱼形态观察与生长研究

为了解黄斑篮子鱼(Siganus oramin)胚后发育特点,对其早期发育阶段进行了形态学观察,并对其各时期的形态特征和生长特性进行了描述与分析。根据卵黄囊和油球消失、仔鱼开口与摄食、鳍膜消退、鳍棘变化、色素沉积和全身被鳞等发育特征,把黄斑篮子鱼胚后发育分为仔鱼期(包括早期仔鱼和后期仔鱼)、稚鱼期和幼鱼期。黄斑篮子鱼初孵仔鱼全长(1.913±0.105) mm,在水温23~24.3℃,3日龄开口;6日龄卵黄囊和油球被完全吸收,进入后期仔鱼期;17日龄鳍膜消失,各鳍发育基本完成,进入稚鱼期;33日龄鳞片覆盖全身,完成变态,外部形态特征与成鱼相近,进入幼鱼期。仔稚鱼生长随日龄的增长呈现出先快后慢再快的生长趋势;第2背鳍棘和腹鳍棘出膜后随日龄不断伸长,28日龄长到最大值,之后逐渐收缩。     

七带石斑鱼胚胎及仔稚鱼形态观察

对七带石斑鱼胚胎和仔稚鱼发育过程进行了观察,描述了从受精卵到仔稚鱼各发育时期的形态特征;在水温22±0.5℃、盐度30条件下进行七带石斑鱼仔鱼的饥饿耐受力实验,记录了饥饿条件下初孵仔鱼的存活与生长、卵黄囊与油球的利用情况。结果表明,胚胎发育可划分为卵裂期、囊胚期、原肠胚期、神经胚期和器官形成期。在水温20.5±0.5℃、盐度30.0条件下,受精卵历时38h45min孵化出膜。初孵仔鱼全长1.059±0.071mm,至4日龄全长2.27～2.36mm时,卵黄囊完全消失;16日龄,全长4.99mm时,鳔形成;至25～30日龄,尾鳍鳍条发育完整。在饥饿条件下,初孵仔鱼的死亡高峰出现在孵化后4～6d,半数死亡时间出现在5d,至7d饥饿仔鱼全部死亡。卵黄囊期仔鱼的生长可分为3个阶段:仔鱼初孵时的快速生长期,卵黄囊消失前后的慢速生长期,以及在不能建立外源性摄食后的负生长期。随着生长发育时间的延长,饥饿仔鱼与正常条件下仔鱼的生长差异显著(P<0.05)。饥饿仔鱼体长较短,头大且体瘦,长期饥饿后脑后部下陷。     

辽河水系洛氏仔、稚鱼形态发育与生长特征

本文研究辽河水系洛氏Phoxinus lagowskii lagowskii仔、稚鱼形态发育和早期生长。结果表明:在18.8~27.2℃下,洛氏初孵仔鱼全长为(4.46±0.43)mm,4日龄的仔鱼鳔一室,5日龄时开始摄食,6日龄卵黄囊完全吸收,13日龄时鳔二室,32日龄时各鳍发育完成;36日龄时开始出现鳞片;58日龄时除头部外全身被鳞,进入幼鱼期。根据卵黄囊、运动器官和鳞片的变化,洛氏早期发育可分为卵黄囊期(孵出0~5d)、后期仔鱼(6~35d)和稚鱼期(36~58d)。曲线拟合表明,卵黄囊体积(V)和全长(LT)与日龄(d)均呈二次多项式关系,相关方程分别为:V=0.0063d2-0.0870d+0.2863(R2=0.8167),LT=0.0083d2+0.2351d+4.8759(R2=0.9544);体质量(W)与日龄(d)呈指数函数关系:W=0.0006e0.1317d(R2=0.9719)。     

西伯利亚鲟仔稚鱼胚后发育的形态学和组织学观察

应用形态学和组织学研究技术对西伯利亚鲟(Acipenser baerii)仔稚鱼发育进行了较详细的观察,通过外部形态变化和内部器官发育情况,对西伯利亚鲟仔稚鱼发育各阶段进行区分。在水温(18.0±1.0)℃,pH 7.0～7.5的条件下,初孵仔鱼平均全长(9.05±0.14)mm,出膜后7日内为早期仔鱼阶段,仔鱼以卵黄囊作为营养来源,视觉是主要的感觉功能;8日龄至22日龄为晚期仔鱼阶段,最显著的特点是卵黄囊已消失,仔鱼转为底栖生活,开始主动摄食,各鳍条及其支鳍软骨逐渐发育完善,视网膜、味蕾、嗅囊和壶腹等器官的分化基本完成;23日龄至57日龄为稚鱼期,主要从骨板开始生长到骨板形成,各器官发育完善,身体各部分比例、体形及体色基本上与成鱼一致为止。西伯利亚鲟主要感觉器官的发育特征与其他硬骨鱼类相比表现出一定的差异,这种差异性充分体现了西伯利亚鲟物种的古老性,在生物进化中占据着重要的地位。     

密斯特黄彩鲶仔、稚、幼鱼的生长与发育研究

在水温22～24℃,pH7.0左右的人工培育条件下,对密斯特黄彩鲶(Mystus sp.)仔、稚、幼鱼的形态特征和生长发育进行了观察与研究。密斯特黄彩鲶的鱼苗发育分为卵黄囊期仔鱼期(初孵至第5天)、晚期仔鱼期(第6～10天)、稚鱼期(第11～20天)和幼鱼期(第20天以后)。初孵仔鱼平均全长5.12 mm,卵黄囊体积1.63 mm3;仔鱼第3天开始摄食,第5天卵黄囊被完全吸收,鱼苗主要外部器官主要集中在晚期仔鱼阶期和稚鱼期内形成。仔鱼在饥饿状态下最高初次摄食率出现在出膜后第6天,为84.0%,其饥饿的不可逆点则为出膜后第8天,第8天以后即进入不可逆PNR期,至第11天绝大部分饥饿仔鱼死亡。     

云纹石斑鱼胚胎发育及仔、稚、幼鱼形态观察

对云纹石斑鱼Epinephelus moara胚胎发育及仔、稚、幼鱼形态进行了观察与研究,详细描述了各发育期的形态特征和发育时间。结果表明:1)在水温22±0.2℃、盐度30、溶氧7.8mg/L、pH8.25的条件下,云纹石斑鱼的受精卵历时38h 17min开始孵化出膜。胚胎发育可分为受精卵、卵裂、原肠、神经胚和器官形成及出膜6个阶段,受精、胚盘形成、2细胞等28个时期。2)在水温23±1℃,盐度30±3,DO≥5mg/L,pH8.0±0.5的海水中,培育至5d,卵黄囊完全消失,成为后期仔鱼;培育至27d,发育最快的云纹石斑鱼结束仔鱼期,进入稚鱼期;培育至65d,发育最快的稚鱼完成变态,成为幼鱼。胚后发育过程主要是根据卵黄囊、鳍膜、鳞片、体色及第1腹鳍棘与第2背鳍棘相对长度的变化分为仔鱼、稚鱼和幼鱼3个时期。其中仔鱼期又根据其卵黄囊的有无划分为前期仔鱼和后期仔鱼。     

棕点石斑鱼(♀)×鞍带石斑鱼(♂)杂交子代胚胎及仔稚幼鱼发育的跟踪观察

本研究阐述了棕点石斑鱼(♀)×鞍带石斑鱼(♂)杂交子代(简称珍珠龙胆石斑鱼)的胚胎发育和仔稚幼鱼形态发育的特征及其养殖过程中的一些难点、要点,以期为今后苗种的规模化培育生产提供参考依据。通过对珍珠龙胆石斑鱼各个发育期连续取样,系统观察并记录各发育期的形态变化及生长特征。结果表明,1)在水温27-28℃条件下,历时25 h 25 min孵化出膜,整个发育过程划分为卵裂期、囊胚期、原肠胚期、神经胚期和器官形成期。2)在水温(27.0±0.5)℃、盐度30、p H 8的培育条件下,根据卵黄囊、第二背鳍棘和腹鳍棘的生长与伸缩及鳞片、体色的变化将胚后发育分为仔鱼、稚鱼、幼鱼3个时期。仔鱼期根据卵黄囊的有无分为前期仔鱼和后期仔鱼。初孵至孵化后4 d为前期仔鱼;孵化后5 d,仔鱼卵黄囊完全消失,成为后期仔鱼;孵化后32 d,50%的仔鱼进入稚鱼期;孵化后46 d,50%的稚鱼完成变态,成为幼鱼。初孵仔鱼的全长平均为(1.65±0.11)mm,发育至70 d时,幼鱼平均全长已达(75.47±0.19)mm。跟踪观察的结果发现,珍珠龙胆石斑鱼作为杂交子代,从受精到发育的各阶段均能健康正常地生长发育,且生长快速、抗病力强,具有"虎斑头、龙胆尾"的外型,具有明显的杂交优势。     

叶尔羌高原鳅胚胎发育与胚后发育观察

采用形态学和生态学方法,对叶尔羌高原鳅[Triplophysa(Hedinichthys)yarkandensis(Day)]胚胎发育和胚后发育阶段全过程进行观察、拍照并测量。结果显示:叶尔羌高原鳅,卵微黏性,略有沉性,受精卵呈卵圆形,卵径为(0.60±0.052)mm,在水温(20.0±1.0)℃下,历时65 h 34 min完成整个胚胎发育分为7个生理阶段过程;胚后发育主要根据卵黄囊、体色、鼓鳔和须的变化分为仔鱼期、稚鱼期、幼鱼期。初孵卵黄囊仔鱼全长(2.0±0.65)mm,出膜后7 d,卵黄囊吸收完毕,完全消失;初孵仔鱼继续培育至16日龄,仔鱼鳃盖后缘鼓鳔明显长出,须清晰可辨,体色加深,心脏红色素明显,体色与成体相似,标志后期仔鱼发育完全进入稚鱼期,此时鱼苗全长(8.0±0.45)mm;培育至30日龄,仔鱼鼓鳔完全,鳃盖张合明显,身体透明特征消失,稚鱼阶段完成发育进入幼鱼期,此时全长达(13.0±0.55)mm,其外部形态和生态习性均与成鱼相似。试验中,卵黄囊长度(LY)和出膜天数(D)的关系式:LY=0.0286D2–0.0636D+3.1196(R2=0.9050);用直线方程拟合卵黄囊长度(LY)和卵黄囊仔鱼全长(LT)的关系式:LY=–1.315LT+5.368(R2=0.8199);拟合卵黄囊仔鱼全长(LT)和出膜后仔稚鱼天数(D)的关系式:LT=–0.0263D2+0.5113D+1.6169(R2=0.9890)。本研究旨在通过了解叶尔羌高原鳅的早期发育特征为该物种的保护和增殖对策提供科学依据,并对其苗种生产提供理论指导。     

Hatching time effect on the intra‐spawning larval morphology and growth in Northern pike (Esox luciusL.)

Based on the analysis of 11 morphometric variables of body (total length, body area and perimeter, myotome height and eye diameter) and yolk sac (length, height, area, perimeter and volume) of pike larvae, the aim of this study was to evaluate how larval size at hatching and growth of larvae hatched from single egg batches vary according to three hatching times: early, mid and late. Hatching time structures strongly pike larval morphometrics. Early hatched larvae have smaller body sizes at hatch, faster growth and higher yolk use efficiency than late hatched ones. Early hatched larvae seem to be premature and hatch at precocious developmental stage whereas late hatched individuals continue their growth within the egg shell and hatch at larger size but with lower reserves (yolk). A compensatory growth phase was observed for the early hatching pike larvae particularly during the first 5 days post hatch. Consequently, no significant difference in body parameters was recorded from day 10 post hatching whatever the hatching time. The higher growth accomplished by early hatched larvae may be related to a particular metabolic activity that converts more efficiently yolk into body tissues.     

Egg incubation and larval rearing of navaga (Eleginus navaga Pall.), polar cod (Boreogadus saida lepechin) and arctic flounder (Liopsetta glacialis Pall.) in the laboratory

The embryonic and larval development of three White Sea cold-water fish species, rate of yolk sac absorption, age at first feeding and their survival and growth when fed different food organisms, were studied.Eggs were obtained from spawners in the Bay of Kandalaksha, White Sea, and incubated in troughs and aquaria at a mean temperature of 1.5 °C, slightly above that of the sea. The incubation period for polar cod eggs lasted 35 days, for arctic flounder, 42 days and for navaga eggs, 48 days. Emergent larvae were 5.5–6.0 mm long and began feeding at 2–4 °C, 5–6 days (navaga) and 12–14 days (polar cod) after hatching, when their yolk sac was still fairly large.They were fed day-old Artemia nauplii and zooplankton taken from the sea and consisting of Calanus and Pseudocalanus nauplii 400–600 μ in length.The period of establishing first feeding is the most critical for larvae.     

Changes in lipid class and fatty acid composition during development in pike (Esox lucius L) eggs and larvae

To establish the changes which occur during embryogenesis and early larval development, eggs, yolk sac larvae and swim-up larvae of pike were examined for lipid class and fatty acid composition. At a water temperature of 15.5°C, the embryonic phase was short (6 days) and characterized by a 41.3% decline in the lipid content of eggs, accompanied by large reductions in the amount of phosphatidylcholine (41.4% decrease), sterol esters and triacylglycerols (respectively a 41.2% decrease and a 58.1% decrease), but not phosphatidylethanolamine which increased markedly (35.6%). By the time of yolk sac absorption (7 to 11 days after fertilization) the larvae remained inactive and a limited utilization of lipids was observed. Yolk sac phosphatidylcholine was selectively incorporated into larval bodies while the levels of other lipid classes remained unchanged in the yolk. When the swim bladder was filled and the swimming stage was reached (11 days to 13 days af), the yolk was completely depleted and yolk phosphatidylcholine together with yolk triacylglycerols were catabolised. Yolk phosphatidylethanolamine and yolk sterol esters were partly incorporated into the body lipids. In the subsequent swim-up larval stage (13 to 15 days af), a steady decrease in lipids was observed (41.6%). Fluctuations in the levels of polyunsaturated fatty acids, monounsaturated fatty acids or saturated fatty acids examined from eggs or larvae were consistent with changes in lipid classes during pike development. During yolk sac absorption, pike incorporated yolk PUFA released on hydrolysis of phosphatidylcholine into the larval body. The results are discussed with reference to water temperature and in relation to the ontogenic and ecological context of pike development. This revised version was published online in July 2006 with corrections to the Cover Date.     

Mortality processes of hatchery‐reared Pacific bluefin tuna Thunnus orientalis (Temminck et Schlegel) larvae in relation to their piscivory

In mass culture of Pacific bluefin tuna Thunnus orientalis, yolk‐sac larvae of other species are fed as a major prey item to tuna larvae from 7 to 8 mm in total length. Marked growth variations in tuna larvae are frequently observed after feeding of yolk‐sac larvae, and this variation in the growth of tuna larvae is subsequently a factor leading to the prevalence of cannibalistic attacks. To elucidate details of the mortality process of hatchery‐reared tuna larvae after the initiation of yolk‐sac larvae feeding, we compared the nutritional and growth histories of the surviving (live) tuna larvae to those of the dead fish, found dead on the bottom of the tank, as direct evidence of their mortality processes. Cause of mortality of tuna larvae 3 and 5 days after the initiation of feeding of yolk‐sac larvae was assessed from nitrogen stable isotope and otolith microstructure analyses. Stable isotope analysis revealed that the live fish rapidly utilized prey fish larvae, but the dead fish had depended more on rotifers relative to the live fish 3 and 5 days after the initiation of feeding of yolk‐sac larvae. The growth histories based on otolith increments were compared between the live and dead tuna larvae and indicated that the live fish showed significantly faster growth histories than dead fish. Our results suggest that fast‐growing larvae at the onset of piscivory could survive in the mass culture tank of Pacific bluefin tuna and were characterized by growth‐selective mortality.     

Ontogenetic development of digestive tract and digestive enzymatic activities in Squaliobarbus curriculus larvae

Squaliobarbus curriculus is an economically important freshwater fish. The ontogenetic development of the digestive system of S. curriculus larvae was studied histologically and enzymatically from hatching to 30 days posthatching (DPH). Amylase, lipase, alkaline phosphatase and pepsin activities were detected from the hatching stage, indicating that these enzymes were genetically preprogrammed. Marked increases in intestinal amylase, trypsin and alkaline phosphatase activities between 10 and 20 DPH corresponded to feed acquisition and transformation. Larval development in S. curriculus could be divided into three phases: phase I (endotrophic period): 1–3 DPH; phase II (endo‐exotrophic period): 4–5 DPH; and phase III (exclusively exotrophic period): from 6 DPH onward. At hatching, the digestive tract of the larvae was an undifferentiated straight tube. On 3 DPH, the digestive tract differentiated into the mouth cavity, oesophagus and intestine. On 6 DPH, feeding was totally exotrophic and the yolk sac was completely exhausted. During the growth of S. curriculus larvae, the intestinal mucosa formed and the number of goblet cells and microvilli increased, demonstrating maturation of the digestive system. The study about the digestive development of S. curriculus larvae will contribute to better larval‐rearing strategies.     

The effects of cadmium and copper on embryonic and larval development of ide Leuciscus idus L.

The effects of Cd and Cu on embryos and larvae of the ide Leuciscus idus were evaluated. The ide is an European cyprinid fish, natural populations of which tend to decrease. The ide is also used as a bioindicator organism to evaluate water quality. However, sensitivity of ide early developmental stages to heavy metal intoxication is not known. Fish were exposed to Cd or Cu (100 μg/L) during embryonic, larval or both developmental periods. Survival of the embryos, time of hatching, size and quality of newly hatched larvae were evaluated at the end of embryonic period. Correctly developed larvae from the control and Cd or Cu-exposed groups were transferred to clean water, Cd or Cu solutions (100 μg/L) immediately after hatching. Larval development was observed, and the larvae were photographed. Time of yolk sac resorption, onset of active feeding and swim bladder inflation were evaluated, and the measurements were done on body and swim bladder size. The results showed that exposure of embryos to Cd and Cu significantly reduced embryonic survival and increased frequency of body malformations and death in newly hatched larvae and delayed hatching. Exposure to Cd and Cu during larval period reduced larval survival, growth and delayed development (yolk utilization, beginning of active feeding and swim bladder inflation). Cadmium was more toxic to the ide embryos and larvae than copper. Exposures to metals during embryonic period alone caused adverse impact on larval performance even when larval development took place in clean water. However, exposure of embryos to Cu reduced toxic impact of metal on larvae in continuous Cu exposure compared to the non-preexposed fish, but no such an effect occurred in case of Cd exposure. The results show that even a short-term exposure to Cd or Cu during early development of ide may adversely affect recruitment of this species. Among the measured endpoints, quality of newly hatched larvae (frequency of body malformations and larvae dead immediately after hatching) and swim bladder size were the most sensitive to intoxication with both metals. Embryos were more sensitive to Cu intoxication than larvae, while in case of Cd, sensitivity of both stages was similar.