大鳞副泥鳅仔稚鱼消化道黏液细胞分布及发育

利用组织学切片及阿利新蓝-过碘酸雪夫(AB-PAS)组化染色技术对0~50日龄大鳞副泥鳅(Paramisgurnus dabryanus)消化道各段黏液细胞的发育与分布进行显微观察和研究。大鳞副泥鳅黏液细胞分为Ⅰ、Ⅱ、Ⅲ和Ⅳ4种类型。消化道黏液细胞最早出现在4日龄仔鱼的口咽腔和食道。10~15日龄口咽腔和食道黏液细胞数量快速增长,15~20日龄肠道各型黏液细胞数量显著增长,20日龄后消化道黏液细胞分布广泛。随着仔稚鱼发育,消化道各部黏液细胞主要以Ⅲ和Ⅳ型细胞为主。根据大鳞副泥鳅仔稚鱼消化道黏液细胞的发育特点,5~10日龄和15~20日龄为其消化道功能发育的两个敏感时期,20日龄后消化道功能逐渐发育完善。建议加强对5~20日龄仔稚鱼的日常饲养管理以提高苗种成活率。     

肠呼吸抑制胁迫对大鳞副泥鳅呼吸代谢和抗氧化能力的影响

为研究肠呼吸抑制胁迫对气呼吸鱼类大鳞副泥鳅(Paramisgurnus dabryanus)的鳃和肠道呼吸代谢及抗氧化能力的影响,初步探究其生理反馈调节机制,本文选取大鳞副泥鳅成熟个体(n=60)进行肠呼吸抑制胁迫实验。分别对实验组(肠呼吸抑制,n=30)与空白对照组(n=30)的大鳞副泥鳅饲养驯化2周,测定其整体静止代谢率、呼吸频率、鳃和肠道各段的乳酸脱氢酶(LDH)、琥珀酸脱氢酶(SDH)、Na+/K+ATP酶(NKA)、过氧化氢酶(CAT)以及超氧化物歧化酶(SOD)活性。肠呼吸抑制胁迫下,实验组与对照组大鳞副泥鳅整体静止代谢率无显著差异(P0.05),而实验组大鳞副泥鳅鳃部呼吸频率显著加快(P0.05)。与对照组相比,实验组大鳞副泥鳅鳃部的琥珀酸脱氢酶活性显著升高(P0.05),而后肠琥珀酸脱氢酶和Na+/K+ATP酶显著降低(P0.05)。同时实验组大鳞副泥鳅后肠的乳酸脱氢酶活性显著升高(P0.05)。实验组和对照组之间,大鳞副泥鳅鳃和前中肠的过氧化氢酶以及超氧化物歧化酶酶活性无显著差异(P0.05),后肠则有显著性升高(P0.05)。当大鳞副泥鳅肠呼吸受到抑制时,会加强其鳃部有氧呼吸代谢,弥补肠呼吸缺失部分,满足机体生理需求,而气呼吸的后肠会有一定氧化应激反应。     

鳜鱼消化道黏液细胞和6种酶的组织化学定位

采用阿利新蓝-过碘酸雪夫氏(AB-PAS)染色和酶组织化学方法对鳜鱼消化道各部位黏液细胞和6种酶的分布与定位进行了研究。结果显示,黏液细胞可为分为4种类型,食道黏液细胞多数为Ⅲ型和Ⅳ型,未见Ⅰ型和Ⅱ型;胃贲门和胃幽门黏膜上皮仅有Ⅰ型黏液细胞;胃体黏膜上皮则以Ⅲ型细胞为主;幽门盲囊中主要为Ⅱ型细胞;前肠和中肠中Ⅳ型黏液细胞最多,Ⅰ型最少;后肠黏液细胞则以Ⅳ型和Ⅱ型为主。酸性磷酸酶(ACP)主要分布于幽门盲囊和前肠的黏膜上皮;碱性磷酸酶(ALP)主要分布于食道、幽门盲囊和整个肠道黏膜上皮;非特异性酯酶(NSE)主要分布于胃幽门、中肠和后肠黏膜上皮;过氧化物酶(POX)在胃幽门黏膜上皮中活性较高;琥珀酸脱氢酶(SDH)主要分布于胃腺中;腺苷三磷酸酶(ATPase)在消化道各部位均有较多分布。鳜鱼消化道黏液细胞和酶的分布型与其它动物有相似之处,也有其一定的特异性,与消化道不同部位的消化吸收机能相适应。     

泥鳅消化道过氧化物酶、三磷酸腺苷酶、琥珀酸脱氢酶、酸性磷酸酶、碱性磷酸酶及非特异性酯酶的分布与组织定位

目的研究过氧化物酶(POX)、三磷酸腺苷酶(ATPase)、琥珀酸脱氢酶(SDH)、酸性磷酸酶(ACP)、碱性磷酸酶(ALP)及非特异性酯酶(NSE)等6种酶在泥鳅消化道不同部位的分布和组织定位。方法在泥鳅食道、胃贲门、胃体、胃幽门、前肠、中肠和后肠等7个部位取样,采用冷冻切片、酶组织化学染色和光密度定量分析等技术。结果POX在食道黏膜上皮细胞中酶活性最高,在胃、前肠、中肠和后肠中酶活性均较低;SDH、ALP和ATPase在食道中酶活性最低,在消化道其他部位酶活性均较高,主要分布于胃黏膜上皮细胞顶部和肠上皮细胞的纹状缘;ACP在食道、胃贲门、胃体、前肠、中肠和后肠上皮细胞中酶活性均较高,胃幽门中酶活性显著较低;NSE在食道、胃贲门、胃幽门、前肠和中肠上皮细胞中酶活性均较高,在胃体和后肠中酶活性显著较低。结论泥鳅消化道黏膜6种酶的分布表明,泥鳅的胃分化程度低,胃和肠道都具有吸收功能;胃贲门、胃体和前肠是蛋白质的主要消化部位;胃贲门、胃幽门、前肠和中肠是脂质的主要消化部位。     

两种泥鳅不同核质关系下LDH同工酶基因表达的研究

采用聚丙烯酰胺不连续系统凝胶电泳方法分析了泥鳅和大鳞副泥鳅不同杂交组合不同核质关系下胚发育阶段（0－145h）中乳酸脱氢酶（LDH）同工酶的分化表达谱式,ＬＤＨ同工酶的基因表达随细胞质、细胞核不同及胚胎发育各个时期具有不同的个体发育谱式,以泥鳅卵子为细胞质的Ⅰ、Ⅱ两组,杂交组（Ⅱ）ＬＤＨ同工酶基因在受精后３min至原肠中期雄核基因参与表达与调控,部分基因位点比本交组（Ⅰ）启动与表达的时间要早,两组的管家酶主要来自细胞质。以大鳞副泥鳅为细胞质的Ⅲ、Ⅳ两组,各酶均以细胞质调控为主,其管家酶与泥鳅有很大不同。并具体分析和讨论了不同核质关系ＬＤＨ同工酶基因的表达和调控的时空顺序。     

银鲳消化道形态与组织学结构特征及其消化酶活性

为了解银鲳(Pampus argenteus)消化道结构特点与其功能及食性的相关性, 采用解剖、石蜡切片、AB-PAS染色及酶活性检测技术对银鲳消化道的形态、组织结构、黏液细胞分布及消化酶活性进行研究。结果显示, 银鲳的消化道由口咽腔(舌)、食道侧囊、食道、胃及肠构成, 胃肠交界处有很多幽门盲囊。食道侧囊呈椭球形, 食道粗短, 胃呈U型, 肠有多个盘曲, 肠指数为2.03。舌上皮内有少量味蕾及较多黏液细胞。食道侧囊、食道、胃及肠均由黏膜层、黏膜下层、肌层及浆膜组成。食道侧囊内皱襞较发达, 被覆复层扁平上皮, 内含较多黏液细胞, 且以Ⅳ型为主, 皱襞顶端及侧面有内含角质刺的次级突起; 黏膜下层及肌层中有固定皱襞的骨质脚根; 侧囊内胃蛋白酶活性较高。食道内皱襞较高, 被覆复层扁平上皮, 内含较多黏液细胞, 且以Ⅳ型为主。胃内皱襞发达, 被覆单层柱状上皮, 未见黏液细胞分布; 胃腺发达, 胃内蛋白酶活性较高。肠道内褶襞多, 高度呈先下降后上升趋势, 黏液细胞密度前、中肠较高, 后肠较低, 且均以Ⅰ型为主; 肠道内胰蛋白酶、脂肪酶、淀粉酶及碱性磷酸酶活性较高。幽门盲囊组织结构与肠相似。银鲳的消化道结构特点、黏液细胞分布及消化酶活性与其功能及偏肉食的杂食性相适应。     

两种海马鳃组织和消化道的黏液细胞类型及分布

运用阿新兰(AB,pH 2.6)和过碘酸雪夫氏(PAS)反应染色方法,对三斑海马(Hippocampus trimaculatus)和日本海马(H.japonicus)鳃组织与消化道中的黏液细胞类型及分布进行了研究。染色结果显示:两种海马的鳃组织和消化道中均含有黏液细胞,日本海马的鳃组织中含有Ⅰ型和Ⅳ型黏液细胞,三斑海马的鳃组织中含有Ⅰ型、Ⅲ型和Ⅳ型黏液细胞。两种海马消化道各部位的黏液细胞类型和数量有明显差异:日本海马的食道中Ⅰ型细胞最多,而三斑海马的食道中Ⅳ型细胞最多;日本海马的前肠中只含有Ⅰ型细胞,而三斑海马的前肠中含有Ⅰ型、Ⅲ型和Ⅳ型细胞,其中Ⅰ型细胞含量最多;日本海马的中肠中含有Ⅰ型、Ⅲ型和Ⅳ型细胞,其中Ⅲ型细胞含量最多,而三斑海马中肠中只含有Ⅰ型细胞;日本海马与三斑海马的后肠中都分布有Ⅰ型、Ⅱ型、Ⅲ型和Ⅳ型细胞,两者不同的是,日本海马的后肠中Ⅲ型细胞含量最多,三斑海马的后肠中Ⅳ型细胞含量最多。     

三种底栖淡水鱼类皮肤黏液细胞分布与数量比较

采用常规石蜡切片以及AB-PAS染色方法研究了葛氏鲈塘鳢（Perccottus glenii）、黄颡鱼（Pelteobagrus fulvidraco）以及泥鳅（Misgurnus anguillicaudatus）3种底栖淡水鱼类的皮肤黏液细胞类型以及分布,计数10个视野下（视野面积为43.5 μm × 32.6 μm）3种鱼类头部、背部、腹以及尾部皮肤的黏液细胞数量,并用单因素方差分析（ANOVA）比较鱼体4种黏液细胞数量差异。结果表明：（1）3种鱼类的主要黏液细胞不同,葛氏鲈塘鳢鱼体黏液细胞中Ⅲ型细胞居多,较Ⅰ型细胞多61.5%,较Ⅱ型细胞多85.8%,较Ⅳ型细胞多85.7%;在黄颡鱼体表,Ⅰ型黏液细胞分布数量最多,较Ⅱ型细胞多9.9%,较Ⅲ型细胞多15.1%,较Ⅳ型细胞多53.5%;而在泥鳅体表以Ⅱ型细胞数量最为丰富,较Ⅰ型细胞多88.3%,较Ⅲ型细胞多33.1%,较Ⅳ型细胞多83.5%。（2）对于葛氏鲈塘鳢,黏液细胞集中分布在头部,比背部黏液细胞数量多15.4%,比腹部黏液细胞数量多出38.0%,比尾部黏液细胞数量多56.7%;黄颡鱼以背部黏液细胞数量为多,比头部黏液细胞数量多42.5%,比腹部黏液细胞数量多46.6%,比尾部黏液细胞数量多51.4%;泥鳅也在背部具有丰富的黏液细胞,比头部黏液细胞数量多49.9%,比腹部黏液细胞数量50.6%。（3）3种鱼类之间的黏液细胞总数不同,泥鳅体表的平均黏液细胞数量最多,相较于葛氏鲈塘鳢多38.9%,较黄颡鱼多39.1%。研究结果表明,不同鱼类的鱼体表面黏液细胞种类不同,可能与其生活环境和鱼体本身的特性有关。     

云南盘鳇消化系统解剖学、组织学及消化酶活性研究

采用形态学、组织学及酶学方法对云南盘逗(Discogobio yunnanensis)成体消化系统进行研究。结果表明, 云南盘逗消化系统有以下特征: 口下位, 口腔上皮分布有较多味蕾及杯状细胞, 食道粗大, 含有大量黏液细胞, 无胃, 肠道较长, 盘旋于体腔中, 成鱼盘旋10回, 肠道系数为5.06±0.61, 肠分为前中后三段, 肠腔中密布肠绒毛。消化腺为肝胰脏, 肝脏分为左右两叶, 胰脏弥散分布在肝脏中。消化系统不同部位消化酶活性大小不同, 脂肪酶活性: 肝胰脏>前肠>中肠>后肠, 胰蛋白酶、淀粉酶、碱性磷酸酶活性: 前肠>中肠>肝胰脏>后肠。云南盘逗口下位, 食道粗短, 肠道细长, 肠绒毛丰富, 肠道含较高的胰蛋白酶和淀粉酶活性, 消化系统所具有的这些特征与其以固着藻类为食有关。     

团头鲂消化道黏膜ACP、ALP、NSE、SDH、ATPase的组织化学定位

目的研究团头鲂消化道各部位酸性磷酸酶(ACP)、碱性磷酸酶(ALP)、非特异性酯酶(NSE)、琥珀酸脱氢酶(SDH)、腺苷三磷酸酶(ATPase)的分布与定位。方法运用冰冻切片、酶的组织化学技术和光密度定量分析。结果 ACP在消化道各段均有分布,后肠酶活性最高,其次为前肠,食道和中肠酶活性最低;ALP在前肠和中肠酶活性最高,后肠酶活性较低,食道中未检测出酶活性;NSE在消化道各段均有分布,前肠酶活性最高,其次为中肠和后肠,食道酶活性最低;SDH在前肠酶活性最高,中肠酶活性较低,食道和后肠未检测出酶活性;ATPase在消化道各段均有分布,中肠酶活性最高,其次为前肠和后肠,食道酶活性最低。结论不同酶在消化道各部位的活力不同,与消化道各部位的生理功能相适应。团头鲂消化道5种酶的分布表明其前肠是脂类的主要消化部位,中肠是营养物质的主要吸收部位,后肠有较强的吸收蛋白质和细胞内消化功能。     

菲牛蛭消化系统的组织学和组织化学研究

利用解剖、HE和AB-PAS染色技术研究了菲牛蛭消化系统的形态结构及组织化学特征。结果表明, 菲牛蛭消化系统由消化管和单细胞唾液腺组成。消化管包括口、咽、食道、嗉囊、肠、直肠和肛门。口开孔于前吸盘腹中部, 口腔内有3片呈三角形排列的颚片, 颚片由辐射肌和横纹肌构成, 其脊上具单列细齿, 可切开寄主皮肤。单细胞唾液腺开口于颚片两侧的乳突上, 可分泌蛭素; 咽呈短球形, 由黏膜层、肌层和外膜构成,肌层发达; 食道短而窄, 黏膜层见少量杯状细胞和大量嗜酸性颗粒; 嗉囊两侧有10对侧盲囊, 最后一对侧盲囊最长且延伸至肛门两侧; 肠部尚无明显分化, 可细分为肠和直肠。肠前段腔内有多个盲囊状的细管, 形成 肠内盲囊, 黏膜层具较多腺细胞, 黏膜下层发达, 具丰富的血管和淋巴细胞; 直肠肠腔明显大于肠的肠腔, 褶皱高度明显比肠的低, 上皮细胞间可见少量杯状细胞。AB-PAS染色结果显示菲牛蛭消化管黏液细胞有4种类型: Ⅰ型被染成红色, Ⅱ型被染成蓝色, Ⅲ型染成紫红色, Ⅳ型染成蓝紫色。口腔部黏液细胞分布以Ⅳ型和Ⅲ型为主, 少量Ⅱ型与Ⅰ型黏液细胞, 咽部以Ⅲ型为主, 食道、嗉囊、肠前部以及直肠壁均无酸性和中性黏液细胞存在, 肠中后部以Ⅰ型为主, 肛门壁存在大量的Ⅱ型黏液细胞。讨论了菲牛蛭消化管结构特点与食性的关系等问题, 发现肠是菲牛蛭整个消化管最主要的消化和吸收场所, 且消化管特殊的结构特征决定了菲牛蛭主要以血液作为食物来源。     

Histochemical distribution of four types of enzymes and mucous cells in the gastrointestinal tract of reared half‐smooth tongue sole Cynoglossus semilaevis

The histochemical distribution of acid phosphatase (ACP), alkaline phosphatase (ALP), non‐specific esterase (NSE), peroxidase (POD) and mucous‐cell types was evaluated in the gastrointestinal tract of the half‐smooth tongue sole Cynoglossus semilaevis. The enzymes were detected in the entire stretch of the gastrointestinal tract. ACP activity was found in the supranuclear region of enterocytes and the lamina propria of the intestine, as well as the cytoplasm of epithelial cells of the stomach. The staining intensity of ACP in the anterior and posterior intestines was stronger than in the stomach. ALP activity was detected in the striated border of enterocytes and muscularis of the whole intestine, lamina propria and supranuclear cytoplasm of the enterocytes in the anterior intestine, as well as in the blood vessels of the stomach. The staining intensity for ALP in the anterior intestine was stronger than in the posterior segment and the latter was stronger than in the stomach. NSE activity was detected in the cytoplasm of the epithelial cells in the entire gastrointestinal tract, with the anterior intestine showing stronger intensity than the stomach. POD activity was located in the blood cells of the lamina propria of the gastrointestinal tract and the levels in the stomach were similar to the anterior and posterior intestines. Alcian blue (pH 2·5) periodic acid Schiff (AB‐PAS) histochemical results revealed three types of mucous cells in the gastrointestinal tract. Type I cells (PAS+AB‐) were observed among the gastric mucosa columnar cells in the stomach and enterocytes in the basal region of the villi and in the middle and top regions of the intestinal villi. Type II cells (PAS‐AB+) and type III cells (PAS+AB+) were not detected in the stomach but were distributed ubiquitously among enterocytes in the middle and top regions of the intestinal villi.     

Anatomical and histochemical features of the digestive system of Octopus vulgaris Cuvier, 1797 with a special focus on secretory cells

This study reports a detailed anatomical and histological study of the digestive system of Octopus vulgaris. Emphasis was placed on characterising the glands and glandular cells and their distribution throughout the digestive tract. The use of classic histological and histochemical techniques revealed two morphological types of glandular cells: granular and mucous. Moreover, the histochemical analysis indicated specialisation of mucous glandular cells in the buccal mass, the submandibular gland and the caecum for secreting acid and neutral glycoconjugates. The cells of the anterior salivary glands are specialised for secreting neutral glycoproteins, and those of the posterior salivary glands are specialised for granular and mucous secretion. The oesophagus, crop and stomach lack glandular cells, but both granular and mucous glandular cells are found in the intestine. An unusual structure resembling the typhlosole of bivalves is described for the first time in the intestine of O. vulgaris. The highly ciliated epithelium and location of the structure in the anterior part of the intestine suggest a possible role in bypassing the caecum, stomach and intestine. We discuss how these cells and organs contribute to the process of digestion in the light of the present histological and histochemical data and of previously published information on the morphology and physiology of digestion in the octopus.     

食蚊鱼消化系统的组织学观察

食蚊鱼的消化道由口咽腔、食道、肠和肛门组成。口咽腔内有味蕾分布。食道粘膜为复层扁平上皮,粘膜内有粘液细胞。肠可分为前后两段,皱襞高度、肌层厚度有差异。消化腺包括肝脏和胰腺。肝小叶不明显,雌雄肝脏的显微结构不同。胰腺呈弥散型,一部分分布在肝脏内,另一部分和消化道伴生。讨论了食蚊鱼消化系统的特点与食性的关系。     

Morphology of the epithelium in the alimentary tract of the larval lamprey,Petromyzon marinus L.

The alimentary tract of the ammocoete of the lamprey, Petromyzon marinus L., is divisible into three morphologically distinct regions: the oesophagus, the anterior intestine, and the posterior intestine. The epithelium of the oesophagus possesses mucous, ciliated, and columnar cells and appears to be specialized for movement of food particles. The epithelium of the anterior intestine possesses secretory cells with numerous zymogen granules, ciliated cells, and columnar-absorptive cells. Although some absorption occurs in the anterior intestine, the main function of this region seems to be the release of digestive enzymes and the continued movement of food particles. The epithelium of the posterior intestine is entirely comprised of columnar absorptive cells, namely tall (light and dark) columnar and low columnar, and the primary function of this region is one of absorption. The epithelium of the hindgut resembles that of the archinephric duct (Youson and McMillan, '71). The morphology of the alimentary tract of ammocoetes suggests that some differentiation and renewal of cell types may occur in the epithelium of the three regions. Comparison of the alimentary tract of larval lamprey with that of other vertebrates indicates that the gut of the ammocoete represents a less specialized level of vertebrate development.     

Morphology and histochemical analysis of glycoproteins in the digestive tract of Dabry's sturgeon

The aim of this study is to explore the morphology and histochemistry of the digestive tract of Acipenser dabryanus (Duméril, 1869). The digestive system of the Dabry's sturgeon contained an oropharyngeal cavity, esophagus, stomach, pyloric caeca, duodenum, valvula intestine, and rectum. Both the pyloric caeca, and the valvula intestine, which belonged to elasmobranch, were present simultaneously in the digestive system of the Dabry's sturgeon, which indicated that it was an archaic species. According to the results, we found four types of mucous cells exist in the digestive tracts of the Dabry's sturgeon. The statistical results showed that there were various types and densities of mucous cells in different parts. In comparison, large quantities of mucous cells existed in intestines. The difference in type and distribution of mucous cells are closely related to the functions of the organs where they are found; 5‐hydroxytryptamine were used to identify the endocrine cells in the digestive tract of the Dabry's sturgeon.The 5‐hydroxytryptamine immunoreactive cells were distributed throughout the digestive tract except the esophagus.