西伯利亚鲟仔鱼侧线系统的发育

鲟鱼属软骨硬鳞鱼,在电感受器的进化中占据着极为重要的地位。该文以光镜和扫描电镜手段研究了西伯利亚鲟侧线系统早期发育,包括侧线基板发育及感觉嵴的形成、侧线感受器的发育和侧线管道的形成。1日龄,听囊前后外胚层增厚区域出现6对侧线基板;除后侧线基板细胞向躯干侧面迁移外,其他侧线基板均形成感觉嵴结构;每一侧线基板中均有神经丘原基形成。7日龄,壶腹器官在吻部腹面两侧出现,壶腹器官的发育比神经丘晚一周左右。9日龄,神经丘下的表皮略有凹陷,侧线管道开始形成。29日龄,在吻部腹面两侧可见少数个别的壶腹器官表皮细胞覆盖壶腹器官中央区域留下3～4个小的开口;壶腹管内可见大量的微绒毛存在,在其他鲟形目鱼类、软骨鱼类中也存在类似的结构。57日龄,躯干侧线管道已完全埋于侧骨板中;壶腹器官主要分布在吻部腹面,3～4个聚集在一起,呈"梅花状",分布紧密,并且该部分皮肤表面凹陷,形成花朵状凹穴;侧线系统发育完善。     

贝氏高原鳅消化系统胚后发育的形态及组织结构

应用解剖学、组织学和组织化学方法,对贝氏高原鳅(Triplophysa bleekeri)消化系统的胚后发育进行观察.结果表明,贝氏高原鳅仔、稚鱼呈线性生长趋势.仔鱼出膜后1～2d为内源性营养阶段,3d进入混合营养阶段,15 d进入外源性营养阶段.初孵仔鱼口凹已经出现,出膜后3d与外界相通,9d口咽腔基本发育完成.8d食道发育基本完成.初孵仔鱼消化道雏形已现,但胃肠未明显分化.出膜后64 d胃小凹处出现胃腺,胃消化功能基本完备.初孵仔鱼肠道已经分化,出膜后27 d肠基本发育完成.初孵仔鱼具有肝前体,出膜后2d肝细胞开始分化,7d肝中出现明显的中央静脉和肝细胞索,肝组织结构与成体差异不大.3d肝前端出现胰组织,4d具有胰雏形,5d完整胰出现,胰腺细胞之间具有大量嗜曙红酶原颗粒物质;9d胰岛出现,胰组织基本发育完成.64 d消化系统各部分组织结构发育基本完成.贝氏高原鳅消化道的形态发育需要很长的时间,出膜后64 d胃肠仅前端膨大,无任何弯曲;85 d胃与食道呈直角弯曲后下行,但胃肠无明显分界;120 d胃弯曲为“Z”形后笔直下行,胃肠仍无明显分界,肝为一整体,未见分叶.1龄幼鱼,消化系统解剖结构与成鱼相似,但肝缺少右叶,肠缺少胃背面的圆环形弯曲.贝氏高原鳅消化系统的胚后发育特点和仔鱼的营养方式可能体现了长江以南地区冬天繁殖鱼类消化系统胚后发育的一般规律和仔鱼的营养趋势.     

Hedgehog参与西伯利亚鲟侧线机械和电感受器分化的初始证据

为揭示Hedgehog（Hh）信号与神经丘和壶腹器官分化的关系,研究以西伯利亚鲟（Acipenser baerii Brandt）为模型,首先对再生过程中的神经丘和壶腹器官的转录组进行比较分析,发现Hh信号通路关键基因（Shh、Patched 1）在两类感受器中差异表达,且它们的表达在再生过程中呈现动态性。然后用环巴胺（Cyclopamine,Hh信号抑制剂）处理西伯利亚鲟胚胎（st29）,用扫描电镜和FM1-43荧光染色对西伯利亚鲟仔鱼（st43-st44）分析发现环巴胺显著抑制了壶腹器官的发育。整体原位杂交表明,Shh、Patched1、Smoothened、Gli2在腹面侧线区域的表达受到了环巴胺的抑制。以上结果暗示Hh信号通路与神经丘和壶腹器官的发育有关,推测Hh信号在神经丘和壶腹器官的分化过程中起到了重要作用。     

重口裂腹鱼眼早期形态发生研究

采用组织学方法观察了实验室饲养的重口裂腹鱼眼在胚胎和早期仔鱼阶段的发生和形态变化过程。结果显示,重口裂腹鱼眼的发生开始于神经胚时期形成的眼原基,眼原基经过分化和内陷形成双层视杯,最终发育形成视网膜。晶状体和角膜来源于外胚层细胞,晶状体发育主要经历晶体板时期;角膜的发育时间较视网膜和晶状体晚,始于角膜上皮的形成。出膜后3 d仔鱼视网膜发育基本完成,眼色素沉积明显,基本具备眼的功能结构。本研究结果丰富了重口裂腹鱼早期发育的生物学资料,为苗种培育等生产实践提供了理论指导。     

暗纹东方鲀侧线系统早期形态和生长发育

通过光镜和扫描电镜对暗纹东方鲀(Takifugu obscurus)的侧线系统进行形态学及组织学的研究。研究结果首次揭示了暗纹东方鲀侧线系统除了主侧线外还包括辅助侧线和辅助神经丘。主侧线分布主要包括眶上线、眶下线、耳后侧线、下颌线、前鳃盖线、上颞线、背侧线、腹侧线。辅助侧线和辅助神经丘分布主要包括口部辅助侧线、眶下辅助侧线、下颌前辅助侧线、下颌后辅助侧线、眶上后辅助侧线、上颞腹辅助神经丘、上颞背辅助神经丘、前鳃盖后辅助神经丘、背部辅助神经丘、尾部辅助神经丘。暗纹东方鲀侧线器官为接受机械刺激的神经丘,数目上千,神经丘分布在体表的凹槽里,且位于高低不同突起顶端。神经丘由套细胞、支持细胞和感觉毛细胞组成。感觉毛细胞呈圆形排列,并且每个细胞的游离面均有一根动纤毛和几十根静纤毛。据本研究对暗纹东方鲀侧线分布特征和神经丘的生长特征等的观察结果,认为尽管暗纹东方鲀侧线系统没有如其他真骨鱼类的管道系统,但是依然具有两套不同生理机能的机械感受系统,符合"七管模式"的主侧线神经丘与管道神经丘同源,而辅助侧线和辅助神经丘才是真正的表面神经丘。     

不同开口饵料对西伯利亚鲟仔鱼生长、存活和体成分的影响

分别采用水丝蚓（Limnodrilus sp.）、卤虫无节幼体（Artemia nauplii）、枝角类（Moina sp.）和人工饲料饲养西伯利亚鲟仔鱼30 d,研究不同开口饵料对西伯利亚鲟仔鱼生长、存活率和体成分的影响.结果表明：卤虫无节幼体为西伯利亚鲟最适开口饵料,仔鱼的存活率最高（96.67%）; 投喂水丝蚓组生长速度最快;而人工饲料组生长速度明显低于其他组,且成活率最低.不同开口饵料组间仔鱼体成分差异显著,人工饲料组水分含量最高,且粗蛋白和粗灰分含量最低.采用卤虫无节幼体为西伯利亚鲟仔鱼开口饵料,然后采用水丝蚓进行强化培育,能获得较好的生长速度和存活率.     

线纹尖塘鳢仔、稚鱼的形态发育

对池养条件下线纹尖塘鳢(Oxyeleotris lineolatus)的胚后发育进行定期观察,胚后发育大致可分为前期仔鱼、后期仔鱼、稚鱼和幼成鱼期。观察发现,线纹尖塘鳢的初孵仔鱼个体较小,仅2.875mm,前期仔鱼,包括混合营养仔鱼期,时间短,仅为5d,属较早建立起外源性营养摄食机制的鱼类;器官发育主要在后期仔鱼阶段完成;鳞的出现和鳞被形成在稚鱼发育阶段完成;在池塘自然水温26~30℃条件下,从初孵仔鱼到稚鱼发育期完成历时43~44d。     

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.     

斑点胡子鲶的胚胎和仔鱼发育观察

斑点胡子鲶胚胎和仔鱼发育分化的次序与同属的胡子鲶相似，但胚胎发育速度较快。在水温２５－２７℃范围内，从受精到孵化出膜的时间约为２６小时，出膜仔鱼４天后卵黄囊被吸收耗尽，并在此前１天开始摄饵；经１２天左右初步完成器官分化发育，总长达１．６－１．８ｃｍ，具有成鱼的基本外观。     

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.     

Dermal morphogenesis controls lateral line patterning during postembryonic development of teleost fish

The lateral line system displays highly divergent patterns in adult teleost fish. The mechanisms underlying this variability are poorly understood. Here, we demonstrate that the lateral line mechanoreceptor, the neuromast, gives rise to a series of accessory neuromasts by a serial budding process during postembryonic development in zebrafish. We also show that accessory neuromast formation is highly correlated to the development of underlying dermal structures such as bones and scales. Abnormalities in opercular bone morphogenesis, in endothelin 1-knockdown embryos, are accompanied by stereotypic errors in neuromast budding and positioning, further demonstrating the tight correlation between the patterning of neuromasts and of the underlying dermal bones. In medaka, where scales form between peridermis and opercular bones, the lateral line displays a scale-specific pattern which is never observed in zebrafish. These results strongly suggest a control of postembryonic neuromast patterns by underlying dermal structures. This dermal control may explain some aspects of the evolution of lateral line patterns.     

Ontogenetic behavior of Siberian sturgeon, Acipenser baerii: A synthesis between laboratory tests and field data

We have reviewed field data and studies on the behavior and development of Siberian sturgeon at early-life intervals and related them to different ecologically relevant environmental factors that may play a role in the distribution, recruitment, and survival of young fish. Four behavioral phases (swimming-up, rheotactism, shoaling, and foraging) are observed from hatching to the juvenile phase. Each behavior is associated with an early-life interval and might allow fish to occupy different river habitats, directly influencing their distribution, survival, and recruitment. River current intensity, substrate typology, food resources, and predation pressure seem to be the most important factors affecting the distribution of Siberian sturgeon free embryos and larvae, while juveniles and adult fish disperse and migrate according to food abundance and reproduction. Mechanisms involved in regulating downstream migration during Siberian sturgeon early life stages are different than those observed in anadromous sturgeon species. In all large Siberian rivers, with the exception of the Lake Baikal, the Siberian sturgeon is represented by population continuums, and in many cases the foraging range also includes the spawning areas. Ontogenetic changes in Siberian sturgeon behavior could be interpreted as a species-specific mechanism to maintain the population continuums described in this species without significant mixture of local populations within the river.     

An Assay for Lateral Line Regeneration in Adult Zebrafish

Due to the clinical importance of hearing and balance disorders in man, model organisms such as the zebrafish have been used to study lateral line development and regeneration. The zebrafish is particularly attractive for such studies because of its rapid development time and its high regenerative capacity. To date, zebrafish studies of lateral line regeneration have mainly utilized fish of the embryonic and larval stages because of the lower number of neuromasts at these stages. This has made quantitative analysis of lateral line regeneration/and or development easier in the earlier developmental stages. Because many zebrafish models of neurological and non-neurological diseases are studied in the adult fish and not in the embryo/larvae, we focused on developing a quantitative lateral line regenerative assay in adult zebrafish so that an assay was available that could be applied to current adult zebrafish disease models. Building on previous studies by Van Trump et al.¹⁷ that described procedures for ablation of hair cells in adult Mexican blind cave fish and zebrafish (Danio rerio), our assay was designed to allow quantitative comparison between control and experimental groups. This was accomplished by developing a regenerative neuromast standard curve based on the percent of neuromast reappearance over a 24 hr time period following gentamicin-induced necrosis of hair cells in a defined region of the lateral line. The assay was also designed to allow extension of the analysis to the individual hair cell level when a higher level of resolution is required.     

Intraspecific divergence in the lateral line system in the nine-spined stickleback (Pungitius pungitius)

The mechanosensory lateral line system of fishes is an important organ system conveying information crucial to individual fitness. Yet, our knowledge of lateral line diversity is almost exclusively based on interspecific studies, whereas intraspecific variability and possible population divergence have remained largely unexplored. We investigated lateral line system variability in four marine and five pond populations of nine-spined stickleback (Pungitius pungitius). We found significant differences in neuromast number between pond and marine fish. In particular, three of seventeen lateral line regions (viz. caudal peduncle superficial neuromasts; canal neuromasts from the anterior trunk and caudal peduncle) showed strong divergence between habitats. Similar results were obtained with laboratory-reared individuals from a subset of populations, suggesting that the patterns found in nature likely have a genetic basis. Interestingly, we also found habitat-dependent population divergence in neuromast variability, with pond populations showing greater heterogeneity than marine populations, although only in wild-caught fish. A comparison of neutral genetic (F(ST)) and phenotypic (P(ST)) differentiation suggested that natural selection is likely associated with habitat-dependent divergence in neuromast counts. Hence, the results align with the conclusion that the mechanosensory lateral line system divergence among marine and pond nine-spined sticklebacks is adaptive.     

Pattern formation in the lateral line of zebrafish.

The lateral line of fish and amphibians is a sensory system that comprises a number of individual sense organs, the neuromasts, arranged in a defined pattern on the surface of the body. A conspicuous part of the system is a line of organs that extends along each flank (and which gave the system its name). At the end of zebrafish embryogenesis, this line comprises 7-8 neuromasts regularly spaced between the ear and the tip of the tail. The neuromasts are deposited by a migrating primordium that originates from the otic region. Here, we follow the development of this pattern and show that heterogeneities within the migrating primordium prefigure neuromast formation.     

Evolution of posterior lateral line development in fish and amphibians

The lateral line is a sensory system present in fish and amphibians. It is composed of discrete sense organs, the neuromasts, arranged on the head and body in species-specific patterns. The neuromasts are deposited by migrating primordia that originate from pre- and postotic placodes and follow defined pathways on the head and body. Here we examine the formation of the posterior lateral line (PLL), which extends rostrocaudally on the trunk and tail. In amphibians, the PLL neuromasts are deposited as a single wave from the head to the tip of the tail. In the zebrafish, however, the first wave of neuromast deposition forms but a rudimentary PLL, and several additional waves are needed to form the adult pattern. We show that the amphibian mode is also present in the sturgeon and therefore probably represents the primitive mode, whereas the zebrafish mode is highly conserved in several teleost species. A third mode is found in a subgroup of teleosts, the protacanthopterygians, and may represent a synapomorphy of this group. Altogether, the mode of formation of the embryonic PLL appears to have undergone remarkably few changes during the long history of anamniote evolution, even though large differences can be observed in the lateral line morphology of adult fishes.     

西伯利亚鲟AdipoR克隆、组织分布及其对禁食的响应

为了探究西伯利亚鲟脂联素受体的表达特征及其对能量状态变化的响应,研究采用RACE方法克隆获得AdipoR1和AdipoR2的cDNA全长.西伯利亚鲟AdipoR1 cDNA全长为2013 bp,开放阅读框为1146 bp;AdipoR2 cDNA全长为1590 bp,开放阅读框为1086 bp.多重序列比对结果显示,西...