日本血吸虫尾蚴发育的超微结构观察：Ⅱ.腺体

在透射电镜下观察不同发育期日本血吸虫尾蚴的腺体。结果：胚球期（Ｓ２）主要出现体细胞分裂与分化,首次证明分泌细胞及其小体在Ｓ２出现,雏体期（Ｓ３）见到前钻腺细胞体与钻腺管束及分泌小体。成熟前期（Ｓ４）钻腺分泌小体基质分Ａ／Ｂ为主两型,分别演变为成熟期（Ｓ）５的后／前钻腺分泌小体。头腺分泌小体亦在Ｓ４出现。从前钻腺体排至头器远端腺管的分泌小体,显眼透明球消失成为致密同质性小体,已为大家共识。而在后钻腺     

日本血吸虫尾蚴发育的超微结构观察：I.体被局部剖析

本文根据日本血吸虫尾蚴发育分期,除胚细胞（Ｓ１）已有报道（胡敏等,１９９１）外,对胚球期（Ｓ２）、尾蚴雏体期（Ｓ３）、成熟前期（Ｓ４）及成熟期（Ｓ５）在透射电镜对体被及其要素进行剖析。结果原（始）体被最早出现于Ｓ２,表性分布。随后（Ｓ３－Ｓ５）消失而为真正体被所取代。体被皱褶亦随高隆。基膜及体棘为名期基本结构。感觉乳突于Ｓ３、Ｓ４出现。到了Ｓ５渐趋复杂而完善并对其结构作了较精细的描述。糖膜直至成熟     

日本血吸虫尾蚴发育的超微结构观察:Ⅰ.体被局部剖析

本文根据日本血吸虫尾蚴发育分期,除胚细胞（ＳＩ）已有报道（胡敏等,１９９１）外,对胚球期（Ｓ２）、尾蚴雏体期（Ｓ３）、成熟前期（Ｓ４）及成熟期（Ｓ５）在透射电镜对体被及其要素（ｔｅｇｕｍｅｎｔａｌ ｅｌｅｍｅｎｔｓ）进行剖析。结果原（始）体被最早出现于Ｓ２,表性分布。随后（Ｓ３—Ｓ５）消失而为真正体被所取代。体被皱褶亦随高隆。基膜及体棘为各期基本结构。感觉乳突于Ｓ３、Ｓ４出现。到了Ｓ５渐趋复杂而完善并对其结构作了较精细的描述。糖膜直至成熟期（Ｓ５）才出现,为尾期成熟的标志。近期对糖膜组份有较深入的研究并对其生理功能进行讨论。     

日本血吸虫胞蚴期超微结构的初步观察

本文用扫描与透射电镜观察了我国大陆品系37日和45日龄日本血吸虫母胞蚴及其体内未成熟子胞蚴体被的结构。同时观察了取自螺肝组织的62日龄成熟子胞蚴。初次揭示日本血吸虫胞蚴期体被的超微结构,基本上与曼氏血吸虫胞蚴期相似。日本血吸虫母胞蚴和成熟子胞蚴除体被无体棘外,其他很相似。比较未成熟的子胞蚴与未成熟的尾蚴,揭示外质膜由两层结构构成;随后,外层结构溶化消失,而同时出现微绒毛。构成这样母子二代胞蚴及其体内胚胎既相同又有差别,认为与幼虫寄生部位及生殖生理状态有关。     

日本血吸虫尾蚴头器、腺体及体被超微结构的观察

本文报告用扫描与透射电镜观察大陆品系日本血吸虫(Schistosoma japonicum)尾蚴的头器、膆体及体被的超微结构。 从不同角度扫描电镜观察日本血吸虫的尾蚴头器前端,见有5对钻腺的开口,开口的周围有围褶,围褶的外侧分布有7对无鞘单纤毛的感觉乳突,这些结构靠近头器的腹侧围成马蹄形,顶端为无棘区。作者综合有关图像重建日本血吸虫尾蚴头器表面结构的示意图,供参考。 日本血吸虫尾蚴的体被、头腺及钻腺与曼氏血吸虫尾蚴基本相似,但在前钻腺分泌小体我们另见有连续性条索状透明物,对它的形成及其性质进行了讨论。     

日本血吸虫子胞蚴超微结构的研究：产孔的形态学证明

本文用透射电镜观察我国大陆品系日本血吸虫子胞蚴前端、收缩区和扩张区的超微结构。发现子胞蚴前端存在体被凹陷区及括约肌的构造,同时可见神经细胞。这个子胞蚴精细分化区可能具有产孔的生理功能,尾蚴从产孔中逸出是非创伤性逸出功能的一种生理适应。并与曼氏血吸虫子胞蚴产孔的超微结构进行了比较。     

曼氏血吸虫中间宿主——藁杆双脐螺

藁杆双脐螺(Biotaphafaria straminea)是曼氏血吸虫中间宿主。曼氏血吸虫(Shistosoma mansoni)是寄生在人体内的血吸虫,生活史与日本血吸虫生活史大体相似,成虫交配产卵,卵随大便、偶从小便排出体外,在水中孵出毛蚴,毛蚴入双脐螺体内,发育成母胞蚴、子胞蚴,尾蚴,然后到终末宿主(人)。曼氏血吸虫与日本血吸虫在终末宿主体内的移行径路极为相似,常能数次通过肝毛细血管、肺及大循环,最后定     

日本血吸虫尾蚴的组织化学及扫描电镜观察

日本血吸虫尾蚴具有一个头腺、2对前钻腺及3对后钻腺,其解剖学位置、构造、化学成分及功能均有区别。钻腺分泌物含有多糖酶及蛋白酶。尾蚴的前端系特化的头器结构,它具有半月形嵴、钻腺开口及乳突。     

腔阔盘吸虫尾蚴及后蚴穿刺腺等腺体的组织化学及其功能的初步研究

本文报道应用组织化学反应方法初步观察了腔阔盘吸虫(Eurytrema coelomaticum)尾蚴及后蚴体中单细胞腺的组织化学成分及其生理功能。尾蚴的5对大单细胞腺主要分泌粘蛋白、酸性粘多糖及微量碱性蛋白质,当子胞蚴被排到外界时,此腺体物质分泌出充满子胞蚴内囊腔并包被着各尾蚴。尾蚴在此腺体分泌物保护下渡过其在外界生存的时间。尾蚴的4对小单细胞腺主要包含中性糖蛋白及结合氨基的蛋白质(可能是含酶物质),此腺体物质可能是在尾蚴进入昆虫宿主(草螽)体内穿钻其胃壁进入血腔时分泌出能溶解胃壁组织帮助尾蚴的穿钻行为。成熟后蚴的穿刺腺对PAS反应呈强阳性,其分泌物可以溶解囊蚴的囊壁,使后蚴迅速脱囊。各幼虫期其他器官组织的组化成分也经观察。     

日本血吸虫皮肤型童虫透射电镜观察

本文报道应用透射电镜观察并比较0.5、3和12小时龄的日本血吸虫皮肤型童虫的超徽结构特征。结果表明,除了外质膜外,其他的超微结构,如体被、肌层、体被下细胞、胞质桥、头腺、钻腺和食道等结构在尾蚴感染后3小时均未见再有明显的变化。     

长尾蚴吸虫幼虫在菲律宾蛤仔的寄生部位及其组织化学的研究

本文报道长尾蚴吸虫幼虫在菲律宾蛤仔的寄生部位及其组织化学的研究,长尾蚴吸虫幼虫主要寄生于哈仔的生殖腺组织中,仅少部分进入生殖腺附近的消化腺,鳃等。受感染严重的蛤仔,其生殖腺的滤泡等组织被虫体占满并被耗尽,长尾蚴吸虫子胞蚴的胞壁及尾蚴的皮导主要含碱性蛋白质和粘蛋白,子胞蚴的胚球,尾蚴的吸盘,生殖原基,单细胞腺体主要ＤＮＡ阳性物质,排泄囊含丰富的碱性蛋白质;尾蚴体的中部含有呈颗粒团的粘蛋白和抗淀粉酶的     

Ultrastructure of the daughter sporocyst and developing cercaria of Schistosoma japonicum in experimentally infected snails, Oncomelania hupensis hupensis

Ultrastructure of daughter sporocysts and cercariae of Schistosoma japonicum were studied 2 and 4 months after infection of Oncomelania hupensis hupensis. The body walls of daughter sporocysts are similar at all infectious stages. They consist of an external syncytial tegument on a basement membrane, and an internal cellular subtegument surrounding a body cavity containing developing cercariae. The cercariae embryos develop 2 months after infection from germinal balls in the brood chamber of the daughter sporocyst. They are at first enveloped by a primitive epithelium rising from the daughter sporocyst. Four months after infection, the cercariae were almost fully developed and the primitive epithelium had degenerated. The body wall of the cercaria consists of a thin tegument covered by a surface coat of fibrous material and connected to the subtegumental cells by cytoplasmic processes. The matrix of the tegument contains numerous dense bodies, vacuoles, and spines. Two types of sensory structures - uniciliated and multiciliated - are found at the anterior tip of the cercaria. There are five pairs of penetration gland cells of two distinct types differentiated by the morphology of secretory granules. Flame cells are found in both daughter sporocysts and in cercariae. The cilia of the flame cells are characterized by the typical 9 and 2 cilium pattern.     

The development of the primitive epithelium and true tegument in the cercaria of Schistosoma mansoni.

The formation of the final cercarial tegument of Schistosoma mansoni is preceded by that of a so-called primitive epithelium. The primitive epithelium is derived from the tegument of the daughter sporocyst. The final cercarial tegument is formed from peripherally located somatic cells of the cercarial embryo, which expand and coalesce beneath the primitive epithelium. The primitive epithelium degenerates and disappears. The ultrastructure of both epithelia in the course of the development of the cercaria is described in detail. Possible functions are discussed.     

Schistosoma mansoni: development of the cercarial glycocalyx

The development of the cercarial glycocalyx of Schistosoma mansoni was studied by transmission electron microscopy and immunofluorescence light microscopy employing antibodies raised against extracted and chromatographed glycocalyx. By electron microscopy, cercariae present in the brood chamber of daughter sporocysts were surrounded by an electron-dense granular and fibrillar matrix. This material appeared structurally distinct from the glycocalyx which was coarsely fibrillar and located only on the surface of organisms that had developed a final tegument. The thickness of the glycocalyx apparently increased with the maturation of the tegument, since teguments that had many spines also had the thickest glycocalyx. Immunofluorescent staining of frozen sections of infected snail hepatopancreas showed that glycocalyx antigens were present on the surface of the cercariae and not in the matrix within the brood chamber or in snail tissues. Immunofluorescent staining of isolated larval cercariae showed staining of some but not all parasites with partially elongated tails. These studies suggest that the glycocalyx develops late in cercarial development (late in Stage 6 or in Stage 7 of Cheng and Bier), is made by the cercariae themselves, and is not a product of either the sporocyst wall cells or snail hepatopancreas.     

Morpho-anatomic and functional sectorization of Schistosoma mansoni daughter sporocysts

During the larval development of S. mansoni in the snail host, morpho-anatomic changes occur in the daughter sporocyst by a sectorization of this larval stage. Three sectors can be distinguished: an anterior zone with a well-differentiated birth pore; dilated zones containing the developing cercariae; constricted zones without cercarial embryo. The photonic and electronic microscopical study shows variations in the tegumental structure of these sectors. This evolution of the daughter sporocysts is discussed in relation with the dynamics of larval stages and the replication process of sporocysts.     

Emergence of the cercariae of Gorgoderina vitelliloba from daughter sporocysts

The daughter sporocyst of Gorgoderina vitelliloba develops attached to the gills of its molluscan host, Pisidium. It has a conical attachment structure at one end of its body through which the birth pore opens. Cercariae emerge through the birth pore, their passage being apparently lubricated by copious secretions from the stylet glands. Only after emergence does the anterior tail chamber envelop the cercarial body to form the typical cystocercous cercaria. When sporocysts were freed from gill tissue and maintained in vitro, cercariae failed to escape from the sporocyst and several encysted, in situ. It is suggested that if this occurred naturally a different host range would be encountered and the long term result might be the evolution of a new species.     

Morpho-functional specialization of the branching sporocyst of Prosorhynchoides borealis Bartoli, Gibson & Bray, 2006 (Digenea, Bucephalidae)

Sporocysts of Prosorhynchoides borealis were obtained from the marine bivalves Abra prismatica and studied using transmission electron microscopy. The sporocyst body consists of a mass of branching and intertwining hollow tubules that ramify through the host's digestive gland and gonads. This study investigated the ultrastructure of the sporocyst branches which comprise alternate distended areas (brood chambers) with a relatively thin body wall, narrower portions with a thicker body wall (constricted areas) and terminal regions. Pronounced differences between these areas were revealed in the structure of their tegument and body cavity lining, as well as in the cellular composition of the subtegumental layers. Body wall composition in distended areas was consistent with the specialization for cercarial nurture in the brood chambers. The structure of the constrictions suggested a dual role of nutrient absorption and physical separation of adjacent brood chambers. Two types of terminal region were identified, one specialized for the investigation and penetration of host tissues and the other, in which the germinal cells are formed, for cercarial production. The overall structure of the sporocyst branches helps explain why this linear modular system, i.e. brood chambers and constrictions continuously growing into the host tissue, enables the sporocyst's long-term existence and can continuously produce cercariae in numbers comparable with those produced by rediae and/or daughter sporocyst infrapopulations in other digeneans. The origin of the nuclei in the outer tegumental layer of some branching bucephalid sporocysts is also discussed.     

Flukes without snails: advances in the in vitro cultivation of intramolluscan stages of trematodes

In vitro cultivation of parasitic helminths, including the digenetic trematodes, has long been a valuable tool in medical and veterinary parasitology, permitting and/or facilitating the development of diagnostic reagents, chemotherapeutic agents, and vaccines and providing insights into naturally complex host-parasite interactions. In vitro cultivation of the intramolluscan stages of trematodes has been particularly challenging, given the ontogenic complexities involved in the production of multiple larval generations from germinal tissues through an asexual "budding" process. Recently, however, advanced larval development has been achieved by incorporating the Biomphalaria glabrata embryonic (Bge) cell line into cocultivation systems. Most notably, the entire intramolluscan cycle (from miracidium to cercaria) has been completed for the human blood fluke Schistosoma mansoni, while significant primary sporocyst development has been attained for several other digeneans including S. japonicum and Fascioloides magna. Here we review recent advances in the cultivation of several larval trematode species and discuss the potential use of this culture system for addressing fundamental questions of host-parasite compatibility.