半滑舌鳎消化系统器官发生的组织学

利用形态学和连续组织切片技术，对出膜后1～30d的半滑舌鳎消化系统胚后发育的组织形态学进行了系统观察和研究。研究表明，试验水温为20．0～22．0℃时，孵化后第3天，仔鱼开口摄食，消化道上皮细胞出现分化，肝脏和胰脏开始出现，鱼体开始由内源性营养转向外源性营养。孵化后第5天，卵黄囊完全被吸收，消化道明显分化成口咽腔、食道、胃、前肠和后肠，仔鱼消化系统具备了摄食和消化外源性食物的能力。此后随着鱼体的生长，粘膜层的褶皱增加，消化道上皮细胞进一步分化，肠道分段、盘旋，消化系统从功能和结构上逐步地完善成熟。开口摄食之后，先后发现在后肠出现嗜曙红颗粒，在前肠出现空泡，表明肠上皮细胞吸收了蛋白质和脂肪。继而糖元在肝脏中不断地储存。在出膜后第23天，出现胃腺，标志着稚鱼期的开始。     

高体革鯻消化道发生的组织学观察

利用形态学和连续组织切片技术,对出膜后1～30d的高体革(鱼刺)消化系统胚后发育的组织形态学进行了系统观察和研究。结果表明,培养水温在26.6～29.7℃条件下,高体革(鱼刺)初孵仔鱼消化管为一柱形盲管,管腔狭窄,口、肛门尚未与外界接通。出膜30h仔鱼,口开始张开,消化管相通。出膜2d仔鱼肠壁出现皱褶,肠瓣将肠道分为前肠和后肠,在显微镜下可见消化管蠕动。出膜3d仔鱼可以开口摄食,消化管上皮分化,食管中出现黏液细胞,肝脏和胰脏出现,鱼体由内源性营养转入混合营养阶段。混合营养阶段仔鱼消化道明显分为口咽腔、食道、胃、前肠、直肠等,消化腺肝脏和胰脏也已形成,各部分已经有初步结构和一定的消化吸收能力。随着仔鱼的发育,仔鱼消化系统各器官也趋于完善。出膜21d稚鱼的胃壁出现胃腺,标志着稚鱼期开始。     

大口黑鲈生长激素促分泌素cDNA结构和早期发育阶段表达谱分析

研究采用RT-PCR、RACE和PCR技术从大口黑鲈胃组织中克隆得到ghrelin基因的cDNA。该基因全长434bp,其中开放阅读框(open reading frame,ORF)321bp,编码107个氨基酸的前肽,20个氨基酸的成熟肽位于第27位到第46位氨基酸处。前肽和成熟肽的氨基酸与已报导的舌齿鲈进行同源性分析,相似性分别为85%和90%。为进一步了解ghrelin基因在鱼体早期发育阶段的表达,本实验采用实时定量PCR(real-time PCR)方法检测了ghrelin基因在大口黑鲈胚胎和仔鱼发育过程的表达谱。结果显示,ghrelin基因在受精卵时期就有少量表达,但直到体节出现之前表达量均较低。出膜第4天ghrelin基因出现大量表达,第12天ghrelin基因表达量更显著增加,出膜第4天和第12天的表达量分别是受精卵时期表达量的206.77倍和531.20倍。出膜第4天正是大口黑鲈仔鱼开口觅食期,仔鱼消化系统初步发育成型,由完全利用卵黄囊营养转为从外界觅食阶段,到出膜第12天,仔鱼消化系统已发育完善,完全依靠外界营养提供能量,由ghrelin基因的表达量变化可推测其可能参与了鱼类早期发育阶段的摄...     

黄颡鱼消化系统胚后发育的组织学观察

在水温22-25℃下,利用组织学方法观察了1-15日龄黄颡鱼(Pelteobagrus fulvidraco)消化系统发育过程.结果发现,破膜后1天,消化道呈裂缝状腔隙,2日龄时食道贯通,卵黄囊很大,为内源营养阶段.3-5 日龄消化道基本贯通,胃腺出现,卵黄变小,被吸收,为肠内-外源营养期.5-6日龄后,卵黄囊被完全吸收,消化系统分化为食道、胃、肠、直肠、肝脏和胰脏等.食道粘膜为复层上皮,富含杯状细胞.颌齿本质加厚,咽齿开始硬化.胃的粘膜上皮为单层柱状土皮,粘膜上皮没有杯状细胞.肠粘膜上皮为单层柱状上皮,肠上皮具杯状上皮细胞.肝小叶分界和肝索明显,进入外源营养阶段.破膜后3天出现独立的胰脏.胰腺外分泌部由许多腺泡组成,破膜后5天出现胰岛,分散存在于外分泌部之间.     

怀头鲇、鲇及其杂交F↓（1）肝、胰脏胚后发育及卵黄吸收方式

利用形态学和组织连续切片技术,对怀头鲇（Silurus soldatovi）、鲇（Silurus asotus）及其杂交F1的肝、胰脏胚后发育和卵黄吸收方式进行对比观察.结果表明,3种鲇出膜后约2天在心脏后方有一肝细胞团,3天后肝细胞团逐步增大,4天后肝分叶.以后随着各种鲇生长速度不同肝、胰脏发育程度也不同.3种鲇的胰脏均为紧凑型,卵黄囊依照先卵黄球、后脂肪的顺序被吸收,3种鲇只有怀头鲇和杂交F1代卵黄吸收方式相同.出膜后4天,各鲇的卵黄均被全部吸收,腹腔上部大部分空间为肝脏占有,同时腹腔内出现结构简单的胃及肠.研究还发现肝脏的发育与卵黄囊密切有关.[中国水产科学,2006,13（3）：460-465]     

哲罗鱼肝脏和胰脏发生和发育的组织学研究

采用形态观察与连续组织切片技术,观察和研究了哲罗鱼（Hucho tai men）肝脏和胰脏在胚胎期（水温7～8℃）和胚后期（水温3～14℃）的发育。结果表明,与大多数硬骨鱼类不同,哲罗鱼的肝脏是在破膜前就开始发生、发育,而胰脏是在破膜后出现,以后逐渐发育完善。受精18 d肝原基细胞出现,破膜8 d,胰细胞出现,破膜8 d肝后部开始贮存脂质,破膜18 d后肝前部开始积累脂质,肝脏发育与卵黄囊有密切的关系。肝脏和胰脏为相互分开的独立器官,具有丰富的肝、胰管。     

哲罗鱼肝脏和胰脏发生和发育的组织学研究

采用形态观察与连续组织切片技术,观察和研究了哲罗鱼（Hucho tai men）肝脏和胰脏在胚胎期（水温7～8℃）和胚后期（水温3～14℃）的发育。结果表明,与大多数硬骨鱼类不同,哲罗鱼的肝脏是在破膜前就开始发生、发育,而胰脏是在破膜后出现,以后逐渐发育完善。受精18 d肝原基细胞出现,破膜8 d,胰细胞出现,破膜8 ...     

大口黑鲈开口摄食与转食人工配合饲料期消化系统发育特征

本研究利用组织切片和扫描电镜技术，观察和研究了2~30日龄大口黑鲈(Micropterus salmoides)仔鱼消化系统的发育过程及组织学变化。结果显示，在水温为(23±1)℃条件下，0~4日龄仔鱼消化道初步分化，为内源性营养期；4~6日龄仔鱼消化道逐渐分化形成食道、胃和肠，胃和肠黏膜褶形成，肝胰脏细胞团出现，仔鱼具备基本摄食能力，进入混合性营养期；10~16日仔鱼消化道和消化腺结构分明，胃、幽门盲囊、肠道紧密排列，肝脏和胰脏独立，进入外源性营养期，此阶段后可逐步转食人工配合饲料。20~30日仔鱼胃腺发达，胃和肠道出现次级黏膜褶，幽门盲囊黏膜褶显著增多、增长，肝脏逐渐出现脂肪积累区，胰脏可见酶原分泌颗粒，肝胰脏组织结构近似成鱼。扫描电镜显示，30日仔鱼胃部内表皮具有丰富的网状黏膜褶，胃小凹间分布着密集的分泌孔；幽门盲囊和肠道内表面结构相似，无固定形态的黏膜褶上布满黏液细胞和分泌孔。20日龄后仔鱼具备转食人工配合饲料的能力。此外，在仔鱼开口和转食人工配合饲料过程中，部分死亡个体的胃肠组织表现出腔体扩大或皱缩，内表皮无成型的黏膜褶或黏膜层脱落，胃和肠道组织损伤。本研究可为大口黑鲈仔鱼开口和转食人工配合饲料条件的优化提供组织学基础资料。     

梭鱼仔、稚、幼鱼消化系统胚后发育的组织学观察

利用形态学和连续组织切片技术,在光镜下系统观察了出膜后1~39 d的梭鱼(Liza haematocheila)仔、稚、幼鱼各期的消化系统发育特征。结果表明,在水温20~22℃时,梭鱼受精卵经50~54 h孵化,初孵仔鱼消化道仅由一条原始的消化管组成。孵出后第4天,上下颌形成,卵黄囊被吸收,消化管盘曲,第一盘曲处形成胃雏形,第二盘曲处及之后形成前肠和后肠,肛门形成并与外界贯通。孵化后第7天,卵黄囊被完全吸收,油球渐小至消失,孵化后第8天,消化系统明显分化成食道、胃、肠、直肠以及肝和胰等,仔鱼由内源性营养向外源性摄食营养过渡。此后,随着仔鱼的生长发育,胃黏膜层的褶皱数量增加,管壁增厚,内腔增大。稚鱼后期,梭鱼苗各鳍初步形成,分化出鳍条,孵化后18 d,幽门盲囊形成,胃腺出现,标志着稚鱼开始消化外源性蛋白,同时,消化道上皮细胞进一步分化,肌层增厚,肠道分段、盘曲,稚鱼食性开始向植食性转换。在此以后,消化系统从功能和结构上逐步地完善成熟。结果表明,梭鱼消化系统的发育与仔、稚、幼鱼的生长、形态发育和消化系统功能的完善相一致。     

不同发育时期月鳢消化酶活性的变化

对月鳢稚鱼、幼鱼和成鱼的主要消化酶活性及分布进行了研究，结果如下：①随着鱼体发育和生长，月鳢消化系统各器官组织的各种消化酶活性不断地增强，尤其是蛋白酶和脂肪酶活性的发育更为明显。②月鳢幼鱼蛋白酶活性以肠组织最大，肝胰脏次之，胃组织最小，且肠组织和肝胰脏中该酶活性显著高于胃组织；胰蛋白酶活性以肝胰脏最大，胃组织和肠组织均表现较小；淀粉酶活性和脂肪酶活性均以胃组织最大，且显著大于肠组织和肝胰脏。③月鳢成鱼蛋白酶活性以中肠粘膜组织和后肠粘膜组织最高，前肠粘膜和肝胰脏次之，胃粘膜最低；胰蛋白酶活性以中肠粘膜组织和前肠粘膜最高，胃粘膜组织次之，肝胰脏小于胃粘膜，后肠粘膜组织的胰蛋白酶活性最小；淀粉酶活性以后肠粘膜组织和中肠粘膜组织最大，肝胰脏次之，胃粘膜组织和前肠粘膜组织最小；脂肪酶活性以胃粘膜组织最大，其他器官组织该酶活性均表现较小。     

Ontogenetic Development of the Digestive System in Agastric Chinese Sucker,Myxocyprinus asiaticus,Larvae

This study was conducted to determine the ontogenetic development of the digestive tract and its accessory structures (liver, pancreas, and gall bladder) in agastric larval Chinese sucker Myxocyprinus asiaticus with the histological and ultrastructural approaches from hatching to 56 days after hatching (DAH). On the basis of its feeding mode, and analyzing the main histological features of the digestive system, larval development in Chinese sucker was divided into three stages from hatching: stage 1 (endotrophic period): 1–6 DAH; stage 2 (endoexotrophic period): 7–14 DAH; stage 3 (exclusively exotrophic period): from 15 DAH onward. At hatching, the digestive tract of the larvae consisted of an undifferentiated straight tube. At 4 DAH, the mouth opened, and the digestive tract was differentiated into buccopharyngeal cavity, esophagus and intestine. At 7 DAH, fish started to feed exogenously. Yolk sac was completely exhausted at 15 DAH. Until 56 DAH, the digestive tract of the larvae displayed regularly arranged microvilli, abundant vacuoles, and protein inclusion bodies. The pancreas, liver, and gall bladder were functional from 6 DAH, which enabled larvae to ingest, digest, and assimilate the first exogenous food. In comparison with teleosts that have a stomach, the development of the digestive tract of the agastric Chinese sucker seemed relatively slow .     

Histological study of the gastrointestinal tract in longfin yellowtail (<Emphasis Type="Italic">Seriola rivoliana</Emphasis>) larvae

This work contributes basic knowledge on larval development of Seriola rivoliana. A histological study describes the development of the digestive tract and accessory glands in S. rivoliana larvae reared under laboratory conditions at 24 °C from hatching to 30 days post-hatching (DPH). At hatching (2.6 ± 0.12 mm), larvae had an undifferentiated digestive tract with a closed straight tube and a large yolk sac with an oil globule. The liver and pancreas were observed at 1 and 2 days, and the mouth and anus opened at day 2. Enriched rotifers were visible in their digestive tract. At the beginning of the pre-flexion stage, a mixed nutritional period was observed. At day 3, exogenous feeding began; the digestive tract became differentiated into the buccopharynx, esophagus, an undifferentiated stomach, and the intestines. Zymogen granules were visible in the exocrine pancreas. At day 4, supranuclear vacuoles were present in the posterior intestine, indicating the beginning of intracellular digestion. At day 5, goblet cells were present in the esophagus and became functional at day 7 in the esophagus and intestine. The buccopharynx goblet cells developed at day 15. The presence of gastric glands and differentiation of the stomach in the fundic, cardiac, and pyloric regions during the post-flexion stage occurred at day 20. This was the onset of the juvenile period and the beginning of weaning; however, a long co-feeding phase is recommended. Pyloric caeca were observed at day 30 (13.6 ± 1.6 mm). These results provide valuable information on S. rivoliana larvae biology and digestive physiology, which should be useful to improve cultivation techniques and identify ecological features involved in ontogeny.     

The ontogeny of the alimentary tract during larval development in common pandora Pagellus erythrinus L.

The ontogenesis of the alimentary tract and its associated structures (liver, pancreas, gall bladder) was studied histologically in common pandora from hatching (0 DAH, days after hatching) until day 50 (50 DAH). Larvae were obtained by natural spawning from a broodstock adapted to captivity. They were stocked in 1500 l tanks supplied with Isochrysis galbana and Tetraselmis suecica from hatching until the Artemia feeding stage, at a temperature of 18.5–20 °C. Larvae were fed Selco-enriched Brachionus plicatilis from day 3, Artemia nauplii from day 28 and formulated feed from day 35. At hatching, the digestive tract was a histologically undifferentiated straight tube lying dorsally to the yolk sac. At first feeding (3–4 DAH) both the mouth and anus had opened and the digestive tract was differentiated into four portions: buccopharynx, oesophagus, incipient stomach and intestine. The pancreas, liver and gall bladder were also differentiated at this stage. Within 2 days after the commencement of exogenous feeding, the anterior intestinal epithelium showed large vacuoles indicating the capacity for absorption of lipids, whereas supranuclear ninhydrin-Schiff (NS) positive inclusions indicating protein absorption were observed in the posterior intestinal epithelium. Both the bile and main pancreatic ducts had opened in the anterior intestine, just after the pyloric sphincter, at this stage. Intestinal coiling was apparent since 4 DAH, while mucosal folding began at 10 DAH. Scattered PAS-positive mucous cells occurred in the oral cavity and the intestine, while they were largely diffused in the oesophagus. Gastric glands and pyloric caeca appeared at 28 DAH, indicating the transition from larval to juvenile stage and the acquisition of an adult mode of digestion.     

美洲黑石斑鱼(Centropristis striata)消化系统胚后发育的组织学观察

通过形态学与连续组织切片的方法,对美洲黑石斑鱼(Centropristis striata) 1-34 d仔鱼消化系统的胚后发育进行系统观察,分析描述鱼体消化道(食道、胃与肠道)以及消化腺(肝脏与胰腺)的发育过程.对1-15 d仔鱼连续取样,每次取样30尾,15 d后隔天取样,每次取样15尾.结果显示,在水温为(24±1)℃、盐度为30-32的条件下,初孵仔鱼卵黄囊体积很大,消化管为封闭的管状结构.美洲黑石斑鱼孵出3d后,口裂形成、开始摄食,肛门与外界连通,消化道逐渐分化形成食道、胃及肠道,肝脏、胆囊和胰腺也逐渐形成.7d后,卵黄囊与油球基本消失,食道、胃部以及肠道黏膜褶皱开始形成,消化道黏膜上皮细胞逐渐分化,肝脏出现脂肪颗粒,仔鱼具备了基本的摄食能力.11d时,仔鱼食道可见黏液细胞,随日龄的增加上皮组织中黏液细胞数量迅速增多,褶皱日益丰富;胃部分化形成贲门部、胃本体与幽门部,胃壁褶皱不断增多、伸长;肝脏血窦与中央静脉明显.20d时,鱼体胃腺形成,说明胃部消化、吸收蛋白质的能力增强;肠道次级黏膜褶皱出现,肠圈与褶皱更加复杂化;胰脏分布有大量酶原颗粒.32 d时,仔鱼消化道组织结构分明,自腔面向内依次为黏膜层、黏膜下层、肌层与浆膜层,消化道与消化腺结构和功能逐步完善.仔鱼3-7 d为内源性营养向外源性营养过渡期,应及时提供充足适口的生物饵料,仔鱼20 d后可以逐渐驯化投喂微型配合饲料.     

Histological development of digestive tract in discus, <Emphasis Type="Italic">Symphysodon</Emphasis> spp. larvae

The present study provides information on the histomorphological development of digestive system of discus, Symphyosodon spp., larvae during the first month of life. Discus larvae are altricial at hatching, with an undifferentiated digestive tract and a large yolksac, which is completely consumed within 7 days. The mouth opens 3 days after hatching (DAH) and the larvae starts feeding on AF Artemia at 4 DAH when offered. At 3 DAH the digestive tract is differentiated with distinct esophagus, stomach anlage, and mid- and hindguts. At 5 DAH, discus larvae is an active feeder, equipped with partly developed jaws and ossified gill arches and an inflated swim bladder. The liver and pancreas are present and supranuclear inclusion vacuoles (SIV) appear in the hindgut for the first time. Gastric glands in stomach were first observed 7 DAH and proliferated by 11–13 DAH. SIV were a common feature in the midgut and hindgut epithelium until 15–23 DAH. Therefore, exclusive use of artificial diets should be postponed until 2–3 weeks after hatching.     

Organogenesis of the digestive system in Pacific red snapper (Lutjanus peru) larvae

This study reports the ontogenetic development of the digestive system of larval Pacific red snapper (Lutjanus peru), an important candidate species for aquaculture on the Pacific coast of Mexico. Histological sections of larvae were cut and dyed using the haematoxylin–eosin technique. The development of the digestive tract of Pacific red snapper larvae follows a general pattern of differentiation that can be divided into three stages. Stage I lasted from 1–3 days post hatching (DPH) and included the endogenous nutrition period; it was characterized by the initial differentiation of the digestive tract in preparation for the onset of exogenous feeding (3 DPH). At this time, the digestive tract was differentiated into buccopharynx, oesophagus, stomach anlage, anterior intestine, posterior intestine and a short rectum. The liver, pancreas and kidney were also present. The mouth and anus were open. Stage II occurred after first feeding, lasted for 16 days (4–23 DPH) and included both preflexion and flexion larvae. The main changes that occurred during this stage reflected the adaptation to exogenous feeding and the concomitant growth. Stage III (24–30 DPH) included post‐flexion larvae and started with the appearance of the gastric glands and pyloric caeca. The presence of the gastric glands suggests that early weaning during culture trials of the Pacific red snapper larvae may be possible at this early age.     

Ontogeny of the digestive tract of larval percula clownfish, Amphiprion percula (Lacépède 1802): a histological perspective

An understanding of the development of the digestive system of marine fish larvae is of critical importance in determining optimal feeding regimes for their culture. The present study provides information on the histomorphological development of the digestive system of clown fish, Amphiprion percula , larvae during the first month of life. Before hatching, clownfish larvae possess an alimentary tract, liver and pancreas with absorptive and digestive capabilities. The yolk sac is completely consumed within 5–7 days at 25 °C. Clownfish larvae readily accept rotifers after hatching and a complete dietary shift from rotifer to Artemia can be accomplished at 10 days after hatch (DAH). Gastric glands in the stomach first develop 11 DAH and proliferate by 15 DAH. Both non-staining vacuoles (NSV) and supranuclear inclusion vesicles (SIV) appear at 11 DAH in the midgut and hindgut respectively. Pinocytosis and extracellular digestion coexist for about 2 weeks after hatching. While SIV disappeared completely at 25 DAH, NSV continued to be a prominent feature of the midgut during the first month.     

军曹鱼消化系统胚后发育的组织学研究

本文利用连续石蜡切片方法对军曹鱼消化系统胚后发育（1～29日龄）进行了光镜观察。结果表明食道前部内侧纵行肌纤维发达，后部球形粘液细胞更丰富；胃腺的分化较晚，在仔鱼后期(即出膜后8天)才见胃腺细胞团。胃幽门部无胃腺，但具发达的肌层。肠上皮的纹状缘出现较早，1日龄时就可见，而且发育较快，3日龄时很发达。 肠后段黏液细胞明显多于前段和中段。肝脏发育较早，但16日龄仔鱼才开始贮存脂质。胰腺为弥散型，2日龄出现。军曹鱼这些结构特点的变化是与其摄食、消化、吸收的功能相适应的，而且，军曹鱼的摄食方式以及食性也随着消化系统的发育而变化。     

Morphogenese de l'appareil digestif et de la vessie gazeuse du turbot, Scophthalmus maximus L.Morphogenesis of the digestive system and swim bladder of the turbot, Scophthalmus maximus L.

The study is based on serial sections made on turbots raised at 18 ± 0.5°C from day 1 (post-hatching) to day 20. Histological changes of the digestive system and swim bladder were observed on a daily basis.At day 1, specimens (total length, Lt = 3.0–3.1 mm) present a digestive tract undifferentiated along its length and closed anteriorly. They belong to the embryonic period in spite of the presence of associated digestive glands (liver and pancreas).The larval period extends from day 2 to day 14–15 (Lt = 3.5–7.0 mm): the swim bladder differentiates and inflates, then the pneumatic duct binding the swim bladder to the stomach degenerates; regional differences appear along the digestive tract which starts to be functional.From day 15–16 (Lt = 6.9–7.7 mm) the juvenile period begins with the formation of gastric glands and the onset of gastric digestion. Two pyloric caeca are clearly visible and the number of intestinal folds and goblet cells increases progressively.