眼斑双锯鱼仔稚鱼发育异速生长

运用生态学和传统理论生物学的研究方法, 对孵化后眼斑双锯(Amphiprion ocellaris)仔、稚鱼在早期生存和环境适应上的异速生长及器官优先发育生态学意义进行了研究, 以期为眼斑双锯鱼人工繁殖和育苗提供参考资料。以11日龄为眼斑双锯鱼仔、稚鱼的区分时期, 结果表明, 眼斑双锯鱼仔、稚鱼的感觉、摄食和游泳等器官快速分化, 均存在异速生长现象。在头部器官中, 吻长、眼间距、口宽和头高在仔鱼期均为正异速生长, 吻至鳃裂前缘长和眼径为负异速生长。在身体各部位中, 仔鱼期体高、躯干长、尾长、尾柄长、尾柄高和体厚均为正异速生长, 仅头长为负异速生长; 在游泳器官中, 仔鱼期眼斑双锯鱼尾鳍、背鳍、胸鳍、腹鳍和臀鳍均为正异速生长。稚鱼期眼斑双锯鱼头部、躯干及游泳等各器官均为负异速生长。眼斑双锯鱼这些关键器官的异速发育, 对适应环境因子变化具有重要的生态学意义。     

红鳍笛鲷仔、稚鱼异速生长

运用生态学和传统理论生物学的研究方法,对孵化后红鳍笛鲷（Lutjanus erythropterus）仔、稚鱼在早期生存和环境适应上的异速生长及器官优先发育生态学意义进行了研究,以期为红鳍笛鲷人工繁殖、育苗提供参考资料。以17日龄为红鳍笛鲷仔、稚鱼的区分时期,结果表明,红鳍笛鲷仔、稚鱼的感觉、呼吸摄食和游泳等器官快速分化,均存在异速生长现象。在头部器官中,吻长、口宽、眼径和头高在仔鱼期均为正异速生长,稚鱼期吻长为等速生长,口宽、眼径和头高为负异速生长。在身体各部位中,仔鱼期头长和体高为正异速生长,躯干部和尾长为负异速生长;稚鱼期体高和躯干长为正异速生长,头长和尾长为等速生长;在游泳器官中,仔鱼期红鳍笛鲷背鳍、腹鳍、尾鳍为正异速生长,胸鳍为等速生长,稚鱼期臀鳍为正异速生长,腹鳍、胸鳍和尾鳍为等速生长,背鳍为负异速生长。红鳍笛鲷这些关键器官的快速发育,使外源性营养开始后以最小的代谢损耗获得了生存能力的显著提升,对挑战和适应纷繁变换的外界压力具有重要的生态学意义。     

鲈鲤仔鱼的异速生长模式

采用实验生态学方法研究了鲈鲤(Percocypris pingi pingi)仔鱼(0～57日龄)的异速生长模式.结果显示:鲈鲤仔鱼全长由慢速生长到快速生长的转折点为25日龄;其多数外部器官均具有异速生长特点,头部和尾部的生长快于躯干部,均在22 ～ 27日龄出现生长拐点;眼径在14 ～ 15日龄较早出现生长拐点,促使眼睛充分发育,以提高早期仔鱼开口期摄食外源食物的能力;吻长在33～34日龄出现生长拐点,促进了口的充分发育,以适应不同的饵料环境;胸鳍、背鳍、尾鳍、臀鳍和腹鳍分别在13～14日龄、31～32日龄、32 ～33日龄、38 ～39日龄、43 ～ 44日龄出现生长拐点,除胸鳍和尾鳍外,其余各鳍的鳍条均在拐点处分化完全,即鲈鲤仔鱼的游泳能力已得到大幅提高.研究表明,鲈鲤仔鱼的异速生长模式,保证了各重要功能器官的充分发育,以适应多变的环境,有效地保障了其早期的生存,可为育苗生产和野生早期资源的保护提供技术支撑.     

施氏鲟仔鱼发育及异速生长模型

施氏鲟仔鱼的生长发育可分为两个时期:卵黄囊期(或称为自由胚期),即从刚出膜(0日龄,10.17±0.63 mm)到初次开口(9日龄,18.93±0.74 mm);晚期,从开口摄食至器官发育基本完全(38日龄,41.89±5.09 mm).卵黄囊期仔鱼的感觉、摄食、呼吸、游泳等器官快速分化;晚期仔鱼各骨板分化并发育,在形态上逐渐完成向成鱼的转变.对施氏鲟仔鱼异速生长进行的研究表明,仔鱼许多关键器官均存在异速生长现象,如眼径、口宽、尾鳍长、胸鳍长分别在2日龄、8～9日龄、10日龄、11日龄出现生长拐点,拐点之前器官快速生长,拐点之后生长速度减慢甚至近似等速生长.施氏鲟仔鱼各器官呈现出协调和快速发育的特征,随着重要的感觉、摄食、呼吸、游泳等器官的发育和完善,仔鱼快速地具备了躲避敌害和摄食的能力,其生存能力大大提高.     

施氏鲟仔鱼发育圾异速生长模型

施氏鲟仔鱼的生长发育可分为两个时期:卵黄囊期(或称为自由胚期),即从刚出膜(0日龄,10.17±0.63 mm)到初次开口(9日龄,18.93±0.74 mm);晚期,从开口摄食至器官发育基本完全(38日龄,41.89±5.09 mm).卵黄囊期仔鱼的感觉、摄食、呼吸、游泳等器官快速分化;晚期仔鱼各骨板分化并发育,在形态上逐渐完成向成鱼的转变.对施氏鲟仔鱼异速生长进行的研究表明,仔鱼许多关键器官均存在异速生长现象,如眼径、口宽、尾鳍长、胸鳍长分别在2日龄、8~9日龄、10日龄、11日龄出现生长拐点,拐点之前器官快速生长,拐点之后生长速度减慢甚至近似等速生长.施氏鲟仔鱼各器官呈现出协调和快速发育的特征,随着重要的感觉、摄食、呼吸、游泳等器官的发育和完善,仔鱼快速地具备了躲避敌害和摄食的能力,其生存能力大大提高.     

日本七鳃鳗胚胎发育及卵黄囊期仔鱼的异速生长

通过观察日本七鳃鳗Lampetra japonica (Martens, 1868)胚胎外部形态和内部组织结构变化, 描述受精卵从卵裂至器官形成以及仔鱼孵出的发育阶段, 采用实验生态学方法研究卵黄囊期仔鱼的异速生长模式。结果表明: 日本七鳃鳗卵子为乳白色, 呈卵圆形; 受精卵卵裂方式为全卵裂; 胚胎发育过程主要包括卵裂期、囊胚期、原肠胚期、神经胚期、头凸期、孵出前期和孵出期, 历时11—12d; 初孵仔鱼为乳白色, 全长约(3.41±0.24) mm, 体质量约为0.0006 g。日本七鳃鳗胚胎发育研究可为了解七鳃鳗胚胎发育过程, 早期脊椎动物的起源和发育进化研究提供参考。卵黄囊期内仔鱼身体各部分中, 头长和尾长均表现出快速生长, 同在7 日龄出现生长拐点, 且生长拐点后的生长速率都大于生长拐点前的生长速率; 而仔鱼体长在卵黄囊期内表现出慢速生长。在头部器官中, 吻长、鳃前长和鳃长均表现出快速生长现象, 吻长和鳃长分别在9日龄和8日龄出现生长拐点; 口笠长在3日龄时出现生长拐点, 在生长拐点前为等速生长, 而在生长拐点后表现出快速生长; 眼径和眼鳃间距则分别表现出等速生长和慢速生长。泄殖孔在卵黄囊期内未出现生长拐点, 生长速率相对于全长生长速率表现出快速生长现象。七鳃鳗卵黄囊期仔鱼的异速生长是在长期进化过程中, 适应早期生活环境和独特的生活方式而形成特有的发育机制。     

斑鰶仔、稚鱼形态发育及异速生长模式研究

运用光学显微镜技术和实验生态学方法, 对斑鰶(Konosirus punctatus)早期形态发育观察、异速生长模式及其生态学意义进行了研究。结果表明: 在水温(21.5±0.5)℃下, 初孵仔鱼全长(3.18±0.52) mm, 斑鰶仔鱼期从孵化出膜到43日龄棱鳞开始出现前, 稚鱼期从44日龄棱鳞出现到55日龄全身覆满鳞片。斑鰶的形态变化和器官分化主要发生在仔鱼期。斑鰶的吻长、躯干长、肠道长、胸鳍长、腹鳍长等重要形态学指标均存在异速生长现象, 其生长拐点依次为 42日龄(TL: 26.41 mm)、24日龄(TL: 15.57 mm)、31日龄(TL: 21.41 mm)、41日龄(TL: 25.47 mm)、42日龄(TL: 26.41 mm)。相对于全长、吻长和胸鳍长在拐点前后由正异速生长变为等速生长, 腹鳍长由正异速生长转为负异速生长, 这为呼吸、摄食和成功逃避捕食者提供有利条件; 而肠道长由负异速生长变为等速生长, 这可能与斑鰶的食性转化有关。综上所述, 为适应复杂多变的生存环境, 斑鰶在早期发育阶段优先发育对生长生存起关键作用的器官, 这对提高仔、稚鱼的存活率具有重要的生态学意义。研究将为今后进一步人工繁育和苗种培育提供理论依据。     

瓦氏黄颡鱼的胚后发育观察

2002年5~6月,在四川省泸州市、合江县分数批收集到长江野生瓦氏黄颡鱼(Pelteobagrusvachelli)亲本,通过人工催产、人工授精获得受精卵,对其胚后发育过程进行了观察。瓦氏黄颡鱼的胚后发育过程可以分为卵黄囊仔鱼、晚期仔鱼和幼鱼3个阶段。初孵仔鱼淡黄色,肌节40对,平均全长5.2mm。水温20~22℃时,孵出后第3d口张开;第7d开始摄食;第9d卵黄吸尽,此时鱼苗平均全长12mm,卵黄囊仔鱼阶段结束。晚期仔鱼阶段的仔鱼,胸鳍、尾鳍、臀鳍、背鳍、腹鳍先后发育,至鳍褶消失时晚期仔鱼阶段结束。经过30d的生长和发育,进入幼鱼阶段;此时平均全长达37mm,其形态特征和生态习性均与成鱼相似。     

拟赤梢鱼的胚胎发育和仔稚鱼生长特性观察

为阐明拟赤梢鱼(Pseudaspius leptocephalus)胚胎发育和仔稚鱼发育特点, 采用人工催产的方式获得受精卵, 观察分析了拟赤梢鱼胚胎发育和仔稚发育的时序特征。结果表明: 拟赤梢鱼成熟卵粒为黄色圆球形, 平均卵径为(1.77±0.20) mm, 遇水具微黏性; 在水温23℃条件下, 胚胎发育经历合子期、卵裂期、囊胚期、原肠胚期、神经胚期、器官形成期和孵化出膜期7个阶段26个时期, 共历时47h 55min完成孵化过程。初孵仔鱼在(23±1)℃水温条件下, 经历卵黄囊期仔鱼(0—7d)、晚期仔鱼(8—26d)和稚鱼期(27—31d), 进入幼鱼期; 卵黄囊期仔鱼游泳能力差, 随着卵黄囊逐渐消耗, 体表色素斑、胸鳍和尾鳍等逐渐形成, 消化道贯通, 鳔充气; 晚期仔鱼卵黄囊完全消失, 仔鱼游泳能力增强, 开口摄食, 腹鳍形成, 皮肤透明; 稚鱼期鳞片形成并覆盖全身, 鱼体形态已逐渐与成鱼无异。拟赤梢鱼仔稚鱼阶段全长生长特性公式为TL=0.0125x2+0.3579x+6.2058 (R2=0.9953), 出膜15d内, 仔鱼生长速度缓慢, 全长日生长率仅为(0.38±0.02) mm/d, 15d后, 仔鱼生长速度变快, 全长日生长率可达(1.24±0.09) mm/d。研究初步阐明了拟赤梢鱼的胚胎发育和仔稚鱼发育的时序特征, 为拟赤梢鱼的苗种规模化繁育提供了理论基础。     

美洲鲥胚胎及仔稚鱼的发育

对美洲鲥(Alosa sapidissima)早期生活史阶段的生长发育特征进行了观察和测量, 描述了胚胎和仔、稚鱼的生长发育特征。美洲鲥受精卵球形、无油球, 为沉性卵, 卵径2.85-3.28 mm。在水温20.3℃-21.9℃孵化条件下, 经过82h 孵化出膜, 根据其胚胎发育过程的形态特征, 胚胎发育分为受精卵、卵裂期、囊胚期、原肠胚期、神经胚期、器官形成期和出膜期7 个发育阶段。美洲鲥初孵仔鱼全长为(8.56±0.36) mm, 其卵黄囊体积为(4.57±0.77) mm3。1 日龄仔鱼脑部发育明显, 口张开, 肛门开通, 胸鳍形成。2 日龄仔鱼卵黄囊体积(0.71±0.23)mm3, 只有刚孵化的15.54%。3 日龄仔鱼经过1d 的混合营养期, 卵黄被完全吸收, 4 日龄仔鱼完全营外源性营养, 卵黄囊的体积(V)随孵化时间(h)的变化方程为V=4.1583e?0.0356h(R2=0.9901)。此后, 背鳍鳍条、尾鳍鳍条、臀鳍鳍条和腹鳍鳍条相继在晚期仔鱼出现, 9 日龄仔鱼尾椎开始弯曲, 21 日龄仔鱼尾椎弯曲完成。27 日龄鱼鳞开始形成, 到33 日龄稚鱼全身披鳞, 个体发育进入幼鱼期, 仔稚鱼期间的生长模型方程为: TL=0.0049D2+0.5091D+9.2578 (R2=0.9885, TL 为全长, D 为日龄)。       

Allometric growth and larval development in Pacific red snapper Lutjanus peru under culture conditions

Allometric growth is a common feature during fish larval development. It has been proposed as a growth strategy to prioritize the development of body segments related to primordial functions like feeding and swimming to increase the probability of survival during this critical period. In the present study we evaluated the allometric growth patterns of body segments associated to swimming and feeding during the larval stages of Pacific red snapper Lutjanus peru. The larvae were kept under intensive culture conditions and sampled every day from hatching until day 33 after hatching. Each larva was classified according to its developmental stage into yolk-sac larva, preflexion larva, flexion larva or postflexion larva, measured and the allometric growth coefficient of different body segments was evaluated using the potential model. Based on the results we can infer the presence of different ontogenetic priorities during the first developmental stages associated with vital functions like swimming during the yolk-sac stage [total length (TL) interval = 2.27–3.005 mm] and feeding during the preflexion stage (TL interval = 3.007–5.60 mm) by promoting the accelerated growth of tail (post anal) and head, respectively. In the flexion stage (TL interval = 5.61–7.62 mm) a change in growth coefficients of most body segments compared to the previous stage was detected, suggesting a shift in growth priorities. Finally, in the postflexion stage (TL interval = 7.60–15.48 mm) a clear tendency to isometry in most body segments was observed, suggesting that growth priorities have been fulfilled and the larvae will initiate with the transformation into a juvenile. These results provide a framework of the larval growth of L. peru in culture conditions which can be useful for comparative studies with other species or in aquaculture to evaluate the changes in larval growth due to new conditions or feeding protocols.     

Pelagic eggs and larvae of Coryphaenoides marginatus (Gadiformes: Macrouridae) collected from Suruga Bay, Japan

The pelagic eggs, yolk-sac and pelagic larvae of the macrourid fish, Coryphaenoides marginatus, from Suruga Bay in southern Japan, are described. The identification of the pelagic eggs based on 16S rRNA gene nucleotide sequences agreed with that obtained from morphological analyses. The spherical eggs, 1.14–1.30 mm in diameter, contained a single oil globule 0.30–0.38 mm in diameter, and had hexagonally patterned ornamentation on the chorion, 0.025–0.033 mm in width. Many melanophores were present on the anterodorsal region of the embryo after the caudal end had detached from the yolk. Within a day after hatching, each of the yolk-sac larvae had a body axis that was bent slightly at the anterior trunk region, many dorsal and lateral melanophores on the trunk plus several on the gut, and small irregular wrinkles on the dorsal and anal fin membranes. The pelagic larvae had a short caudal region in comparison to other known congeners (length 2.0–3.2+ times head length vs. 4–7, respectively), a short stalked pectoral fin base, and no elongate first dorsal and pelvic fin rays. They were further characterized by the presence of numerous very dense melanophores from just behind the eye to the anterior part of the caudal region at 5.1 mm head length (25.8+ mm total length). The significant difference in vertical distribution between the pelagic eggs and larvae (dominant depths ca. 200–350 m vs. ca. 10–100 m, respectively), with no subsequent collection of pelagic larvae with greater than 6 mm head length, indicate two stages (rising and falling) of ontogenic vertical migration.     

Larval development of Argentine hake Merluccius hubbsi

The ontogeny of the developmental stages of the hake Merluccius hubbsi is described. Fish larvae and post-transitional juveniles were collected in the Nor-Patagonian area from 1989 to 2004. The opening of the mouth and the pigmentation of the eyes are coincident with yolk resorption, finishing the yolk-sac stage. This species presents pigmentation on the head, trunk and tail typical of gadiform larvae. Pectoral fin development is completed during the transformation stage. The post-transitional juvenile stage begins when the fin-ray complements are complete and squamation begins. The fins become fully formed in the following sequence: pelvic fins, first dorsal fin, second dorsal and anal fins together, caudal fin and pectoral fins. The caudal complex is totally developed in larvae of 22·0–23·0 mm standard lengths ( L _S) and all vertebral elements are first observed in larvae of 8·5 mm L _S. The rate of development of M. hubbsi observed in this study could be faster than the rates reported for other species of Merluccius by different authors.     

Larval development of Hypsophrys nicaraguensis (Pisces: Cichlidae) under laboratory conditions

The cichlid Hypsophrys nicaraguensis is a popular fish known as butterfly, and despite its widespread use as pets, little is known about its reproductive biology. In order to contribute to this knowledge, the study describes the relevant larval development characteristics, from adult and larval cultures in captivity. Every 12h, samples of larvae were collected and observed under the microscope for larval stage development, and every 24h morphometric measurements were taken. Observations showed that at 120h, some larvae had swimming activity and the pectoral fins development was visible; at 144h, the dorsal fin appear and all larvae started food intake; at 168h, the formation of anal fins begins, small rudiments of pelvic fins emerge, the separation of caudal fin from anal and dorsal fins starts, and the yolk sac is reabsorbed almost completely; at 288h, the pelvic fins starts to form; at 432h, the rays and spines of dorsal and anal fins can be distinguished, both the anal and the dorsal fins have the same number of spines and rays as in adults. After 480h larvae have the first scales, ending the larval stages and starting the transformation to fingerlings. Larvae were successfully fed with commercial diet.