Ultrastructure of the cirrus pouch of Cylindrotaenia hickmani (Jones, 1985) (Cestoda, Nematotaeniidae)

The cirrus pouch of Cylindrotaenia hickmani was examined by transmission electron microscopy. The cirrus pouch is a complex organ consisting of muscular, nervous and epithelial tissues. Muscles forming the cirrus pouch wall contain large myocytons that merge with myofibrils. Muscles supplying the gonadoducts within the pouch consist of small myocytons which are connected to associated myofibrils by elongate processes. Discrete neuromuscular junctions are commonly seen in both muscles. Two cells, thought to be neurons, are present in the pouch. The abundance of nervous tissue in the pouch is suggestive of a high level of neural control of the activity of that organ. The cirrus is lined by filamentous, hook-like and blade-like microtriches. Ciliated sensory receptors are found among the microtriches lining the cirrus. Epithelial cytons associated with proximal regions of the cirrus produce a material which is secreted from the syncytial cytoplasm of the cirrus. Intercellular junctions, resembling gap junctions, are common among the cells associated with the cirrus. The complexity of the cirrus pouch of C. hickmani suggests that this organ may prove valuable for studies on neuromuscular physiology and cellular interactions in cestodes.     

Comparative study of the microtriches of adult Cestodes (Proteocephalidea: Monticelliidae), and some comments on their systematic value

The surface of the tegument of the scolex and the immature proglottides of Monticellia belavistensis, M. ventrei, Nomimoscolex chubbi, and N. lopesi is described using scanning electron microscopy. Only blade-like spiniform microtriches and filiform microtriches were observed in the species studied. The types, size and density of microtriches on the apical region surface of the scolex, central cavity surface of suckers, marginal ring surface of suckers, non-adherent surface of suckers, proliferation zone surface, and immature proglottis surface were compared among these species. The distribution pattern of the microtriches was not a reliable feature to discriminate among the genera considered in this study. It varied in each of the species of Monticellia examined, and did not permit to split the heterogeneous genus Nomimoscolex. However, the microthrix pattern can be regarded as an additional diagnostic feature to distinguish among species of proteocephalideans. Further comparative research involving other species of proteocephalid taxa is needed to elucidate the systematic value of the tegumental morphology.     

Ultrastructure of the cirrus sac of echinophallid tapeworms (Cestoda, Bothriocephalidea) and the terminology of cirrus hard structures

Transmission (TEM) and scanning (SEM) electron microscope methods were used to study the fine structure of the cirrus, cirrus sac, internal seminal vesicle, ejaculatory duct, prostate glands and cirrus armature of Echinophallus wageneri (Monticelli, 1890) and Paraechinophallus japonicus (Yamaguti, 1934) (Bothriocephallidea: Echinophallidae). The cirrus sac of these species has two unique ultrastructural features: a thick wall with two bands of muscles and prominent, rooted hard structures. Rare traits echinophallids share with diphyllobothriideans are microtriches on the ejaculatory duct and with spathebothriideans, well-developed unicellular prostate glands outside the cirrus sac. Because there is a similarity of cirrus armature and rostellar hooks in having a tegumental localisation and in having a heterogenous structure of the blade and root, a cortex, a central pulp region and a recurved apex, these structures are named “modified hooks” instead of spines. They also have a spiral arrangement; no base plate was observed. True spines, as found in trematodes, are between the surface and basal plasma membrane of the external syncytial layer of the tegument, rest on the basal plasma membrane of the distal epithelial cytoplasm, show a homogeneous electron-dark crystalline appearance and are covered by the surface plasma membrane. Aside from the characteristic hooks on the scolex of various cestodes, we see no evidence that would preclude the development of still other specialised structures, such as these modified hooks, from microtriches. In spite of the absence of studies on the development of modified hooks from the cirrus of echinophallids and/or its consideration as derived from microtriches, we assume that like microtriches, formation of modified hooks is from tegumental bodies and therefore they are derivative structures of the cestode tegument.     

鱊头槽绦虫原尾蚴皮层的超微结构观察

利用透射电镜观察了头槽绦虫 (Bothriocephalusacheilognathi)原尾蚴皮层的超微结构。头槽绦虫原尾蚴的皮层为典型的合胞体结构。皮层表面有浓密的微毛与少量的突起。与成虫相比 ,原尾蚴的微毛长而且粗 ,呈现单态性 ,推测在进入终末宿主的过程中有脱落和再生现象。突起分布在头部与体侧 ,含有较少的电子致密颗粒。在原尾蚴皮层细胞质中观察到三种腺细胞的分泌过程 ,即顶分泌、外分泌和微分泌过程。原尾蚴身体后部观察到尾钩和穿刺腺管道的开口。在核周区和纤维层下可见发育较好的环肌与纵肌。本文还对原尾蚴皮层突起的功能进行了探讨。     

An electron microscope study of the tegument of Hunterella nodulosa Mackiewicz and McCrae, 1962 (cestoidea: Caryophyllidea)

Ultrastructural observations using transmission and scanning electron microscopy reveal the tegument to be basically similar to that of other cestodes. The syncytial distal cytoplasm is devoid of organelles except for rod-shaped bodies, believed to be secretory vesicles, and lamellated bodies which probably contribute the raw material for new microtriches. There is evidence that these vesicles originate from the Golgi found in the sub-cuticular cells.Three types of microtriches are described: typical ones with well-developed spines, ones with short filaments instead of spines, and ones with no spines. Microtriches with spines are found only on the anterior part of the worm and may serve to anchor the worm. Microtriches on the posterior have no spines and are believed to be primarily involved in the absorption of nutrients. Between these two regions there is a transitional zone where all three types of microtriches can be found. In general the microtriches are quite uniformly distributed throughout the surface of the worm. The presence of cestodarian-like microtriches raises interesting evolutionary questions.Histochemical tests localized acid and alkaline phosphatase activity on various parts of the tegument, as well as on host intestine, while acian blue tests showed that acid mucopolysaccharide levels correspond with the concentration of the tegument vesicles.     

Proliferation and metastases formation of larval Echinococcus multilocularis. II. Ultrastructural investigations

The larval stage (metacestode) of Echinococcus multilocularis was studied by means of electron microscopy (SEM, TEM) before and after subcutaneous transplantation to jirds (Meriones unguiculatus) and in their lymph nodes and lungs with parasite metastases. It was found that the metacestode consists of a network of solid, cellular protrusions (buds) of the germinal layer which transform to tube-like and cystic structures devoid or with a laminated layer. Proliferation of the metacestode apparently occurs by protruding filamentous solid cell columns (buds) from the germinal layer. Their tips have diameters of only one cell: they are covered with a smooth syncytial tegument without microtriches and are filled with undifferentiated cells which contain a nucleus with a large nucleolus. The tegument is constantly enlarged by fusion with the underlying undifferentiated cells that divide repeatedly. At some distance from the tip a cavity develops inside the protrusion, thus finally giving rise to a tube-like structure which may transform to a cystic expansion. Simultaneously, the surface of the protrusion changes by the formation of microtriches and the occurrence of an amorphous laminated layer. The latter is concentrically covered by connective tissue cells and large amounts of collagen. Within cyst-brood capsules, finally protoscoleces are formed from accumulations of undifferentiated cells beneath the tegument. The study has unequivocally proven the cestode nature of the cellular protrusions, and it is assumed that detachment of cells from these structures and their subsequent distribution via the circulation may play a role in the formation of metastases. The origin of the laminated layer is discussed.     

Ultrastructural adaptations for viviparity in the female reproductive system of gyrodactylid monogeneans

The female reproductive system of viviparous monogeneans (Gyrodactylus and Macrogyrodactylus) has been examined using fluorescence microscopy and transmission electron microscopy. The female system is tubular, made up of a thin-walled proximal seminal receptacle/ootype and a distal uterus, separated by a complex cellular region. Both parts have a continuous syncytial cytoplasmic lining. Maturing oocytes in the seminal receptacle/ootype are in intimate contact with the receptacle lining. The uterus cytoplasmic lining completely surrounds the developing embryo, and is continuous with anterior and posterior cell bodies which fluoresce strongly when stained with bisBenzimide. This lining is most extensive around small embryos, when it contains specialised organelles including star-shaped configurations of electron-dense membranes and multilamellate bodies. Pits in the uterus wall bridged by membranous structures connect the cytoplasmic lining to parenchyma or digestive cells. The cytoplasmic lining regresses as the embryo develops, but remains continuous and in intimate contact with the embryonic tegument (at least until the near-term embryo begins independent movement). Numerous ribosomes, membranes and mitochondria in the uterine cytoplasmic layer indicate a high metabolic rate, and exo/endocytotic vesicles in the F1 tegument suggest transfer of materials occurs between parent and embryo. Putative vitelline cells in the posterior of the body contain abundant RNA, ribosomes and membrane-bound secretory bodies, and are filled with an electron-lucent secretion. However, there are no ducts associated with these cells, and their function remains unknown. The cytoplasmic lining of both the seminal receptacle/ootype and the uterus appears to regulate oocyte/embryo nutrition. Similar syncytial layers occur in rotifers, but are unlike the nutritive epithelia of most other viviparous organisms.     

The ultrastructural architecture of the adult Schistosoma japonicum tegument

The tegument of the adult blood fluke Schistosoma japonicum is in direct contact with the host blood and immune systems. A comprehensive understanding of the ultrastructure of the tegument is crucial to the understanding of how the parasite maintains itself within the mammalian host. Important functions such as nutritional uptake and immune evasion are suspected functions of the tegument and this review discusses these aspects and presents some insights into some of these crucial functions. Transmission electron microscopy has allowed the identification of ultrastructural features of the adult S. japonicum, some of which differ from the reported features of other schistosome species. Morphological differences within the tegument of the adult S. japonicum are noted between sexes, among different regions of the worms and between aspects along the length of the parasite. Differences included variations in the ultrastructure, size and number of tegumental bodies and mitochondria within the matrix, and differences in the relative area of the apical surface of the tegument. Functions of the various components of the tegument matrix and specialised functions of different regions of the male and female parasites are discussed based on ultrastructural findings and previously reported biochemical and molecular data.     

The fine structure of the cysticercoid of Hymenolepis diminuta. III. The scolex.

Transmission electron microscopy of the scolex of the 8-day-old Hymenolepis diminuta cysticercoid demonstrates its resemblance to the scolex of the adult. A syncytial tegument composed of external and internal layers is connected by cytoplasmic extensions. Fully developed microtriches are present. Furthermore, a basement membrane, muscle layers, and medullary region containing flame cells, nerve tissue, and other cell bodies are observed. Of particular interest is the presence of discrete sensory endings whose function is discussed.     

中国罗汉松属叶角质层微形态结构及其分类意义

利用扫描电镜对罗汉松属8种2变种植物叶角质层内外表面进行了细致观察。发现罗汉松属植物叶角质层结构具有许多相似特征,表皮细胞较为规则,长方形或多边形,边缘波状弯曲;气孔器排列成带状,长轴均与叶脉一致,气孔器具较为明显的气孔塞和伏罗林环,气孔器保卫细胞极延伸明显,通常具有2~4个副卫细胞、不具极副卫细胞。但罗汉松属叶角质层结构也具有明显的种间差异,镰叶罗汉松和洛杉矶罗汉松同其它种类差异最大,这两种植物叶两面均具气孔器,角质层内表面垂周壁直,角质层凸缘不明显;贺氏罗汉松最为显著的特征是近轴面和远轴面表皮细胞的垂周壁角质层厚且凸缘均极其发达;小叶罗汉松近轴面表皮细胞排列较为规则,多数为方形,长轴与叶脉垂直,垂周壁之间的角质层突起较为显著,延伸到皮下层;兰屿罗汉松近轴面表皮细胞排列较不规则,多边形,细胞的角端比较钝,没有棱角;大理罗汉松气孔带间隔较小,有时两条气孔带挤在一起,使副卫细胞紧连,近轴面表皮细胞较短,方形或长方形,垂周壁之间的角质层较不发达;海南罗汉松角质层气孔带间隔较宽,气孔器形状为阔椭圆形,近轴面表皮细胞均为细长方形;变种短叶罗汉松和狭叶罗汉松与罗汉松也具有明显差异,短叶罗汉松近轴面表皮细胞排列不规则,垂周壁深波状弯曲,凸缘极为明显,但原种罗汉松近轴面表皮细胞排列较为规则,垂周壁浅波状弯曲,凸缘不明显,而狭叶罗汉松近轴面表皮细胞方形或长方形,比罗汉松的表皮细胞短,垂周壁直或略弯曲,角质层极厚。这些角质层微形态特征差异可以作为罗汉松属内种类分类鉴定的依据。     

Cyton II: A subtegumental cell type in the cercaria of Schistosoma mansoni

In Schistosoma mansoni cercaria, an aggregate of subtegumental cells is found in a small, dorsoanterior area of the body (middivision). These cells are nestled between two laterally positioned flame cells and the muscle that delimits the anterior end of the body, and the anterior end of the central ganglion. This highly amorphous cell type, designated as cyton II, has a heterochromatic nucleus and a cytoplasm that is elaborated into coarse, tortuous processes. Its cytoplasm contains ribosomes, mitochondria, sparse amounts of endoplasmic reticulum, and two types of circular-to-oval concentric membranous bodies. One type has an electron-dense core and measures 200–250 nm on the short axis, and the other is completely membranous and measures 100–125 nm on the short axis. The cell body of cyton II communicates with the tegument that covers a small, dorsoposterior area of the anterior organ (oral sucker); however, we could not confirm a tegumental connection with the body division. When cercariae transform into schistosomules, the concentric membranous bodies of cyton II migrate into the anterior organ's tegument via cytoplasmic processes of the cell. The major function of previously described cells that have similar membranous bodies is to supply additional membranes to the outer tegument during development into an adult worm. A multilaminated outer membrane is an adaptation to the survival of the schistosomule and adult worm in the bloodstream of the vertebrate host (Hockley amd McLaren [′73]). The presence of membranous bodies from cyton II in the tegument does not confirm that this cell type participates in the formation of multilaminated membranes. Its precise function remains to be determined. © 1995 Wiley-Liss, Inc.     

Taenia taeniaeformis (Cestoda) in the rat: ultrastructure of the host-parasite interface on days 8 to 22 postinfection

The host-parasite interface was examined at the ultrastructural level 8 to 22 days postinfection (DPI) with metacestodes of Taenia taeniaeformis in the rat. Throughout this phase of development the parasite surface was invested with a dense surface coat of complex microtriches. At 8 to 14 DPI the plasma membrane of each microthrix extended beyond the distal end of the electron-dense tip, forming a slender tubular streamer over 10 microns long; by 18 DPI these had shortened and withered. Host cell processes interdigitated with the microtriches without evidence of harm to the parasite surface or the underlying tegument. The cells, on the other hand, became damaged, and their contents were shed into the matrix surrounding the microtriches. Lipid inclusions appeared within the parasites, and in the cytoplasm of surrounding inflammatory cells. By 22 DPI fibroblastic activity had resulted occasionally in the formation of a capsule surrounding a free-floating cysticercus, while in others intense granulocytic infiltration persisted with abutment and intermeshing of host cell and parasite surface processes; however there was still no evidence of any adverse effect on the microtriches, though many granulocytes were clearly pyknotic and degenerating. Evidently, the vigorous cellular response of the host is ineffective in either containing the expansion of the parasite or compromising the integrity of its surface membrane. The changing characteristics of the microtriches may be related to the need for dissolution of both intercellular matrices, and host cells as the vesicular organism rapidly increases in volume.     

Morphological studies on the early development of Taenia taeniaeformis larvae in susceptible mice

Bortoletti G. and Ferretti G. 1985. Morphological studies on the early development of Taenia taeniaeformis larvae in susceptible mice. International Journal for Parasitology15: 365–375. Taenia taeniaeformis larvae which develop into infective strobilocerci in C3H mice have been studied from the 5th to the 15th day of development (L5–L15), both at light and electron microscope level. The L5 were initially compact, without a central cavity but then become vacuolized. Until stages L7–L8 they were surrounded by a perilarval amorphous layer (PAL) made up of a finely granular material which prevented the host cells from making contact with the larval tegument. The larval volume increased considerably between stages L6 and L8, remained unchanged from L9 to L13, but continued to increase thereafter. The larval cellular layer, which appeared as a single, large ‘syncitial system’, grow until stages L14–L15 when the scolex anlagen began to form. The tegument was initially incompletely organized and was covered by microvilli. These were completely replaced by microtriches from stage L8 onward. Sometimes both microvilli and microtriches were together observed in stage L7. Microvilli fragments, sometimes beaded, could be observed at L5 within the damaged cytoplasm of host cell debris. Very often they were branched at different heights, especially in stages L5–L7. In L10–L15 all undamaged microtriches increased in density and formed bundles which invaded the host cells. In stages L5–L8 and in some L9, muscular bundles started to become organized inside the tegumental distal cytoplasm (TDC), and after become independent in the subtegumental cellular layer (SCL). Until L8–L9 the larvae were surrounded by host cells debris. From stages L8–L10 onwards the adjacent host cells were less damaged though the larval microtriches penetrated them deeply. In stages L5–L7 neutrophils together with macrophages and some damaged hepatocytes were detected, while eosinophils were present only from L8 onward. In the other stages neutrophils clearly diminished in numbers, whereas macrophages had increased. No mastcells and few plasma cells were observed.     

An ultrastructural study of alimentary tract development in the cercariae of Prosorhynchoides borealis (Digenea,Bucephalidae)

Podvyaznaya I. 2011. An ultrastructural study of alimentary tract development in the cercariae of Prosorhynchoides borealis (Digenea, Bucephalidae). —Acta Zoologica (Stockholm) 92 : 170–178. The development of digestive system in Prosorhynchoides borealis cercariae was studied using transmission electron microscopy. The foregut and caecum primordia arise in early cercarial embryos as two adjoining cellular cords. The primordial pharynx appears as a cluster of myoblasts in the mid‐part of the foregut primordium whose proximal end abuts onto the ventral embryonic tegument. Later, a lumen develops within the gut primordia and their component cells form the embryonic cellular epithelium with an essentially similar structure in the foregut and caecal regions. Subsequently, the foregut epithelial cells merge to form a syncytium. This process proceeds asynchronously and the most proximal foregut area remains cellular for the longest time. The syncytial lining of the foregut establishes syncytial connections with secretory cytons differentiating in the surrounding parenchyma. These cytons produce secretory granules, which are transported through cytoplasmic connections to the foregut syncytium. Before cercariae reach maturity, their foregut epithelium becomes anucleate and continuous with the external tegument. By the end of cercarial development, numerous short lamellae appear on the luminal surface of the caecal epithelium. The caecal cells become involved in secretory activity as indicated by the presence of Golgi‐derived secretory bodies in their cytoplasm.     

Hymenolepis microstoma: Ultrastructural localization of adenyl cyclase in the tegument

Peroxidase and phosphatase activities have been reported to be localized in the tegument of adult hymenolepidid tapeworms. In order to localize adenyl cyclase (EC 4.6.1.1) activity in the tegument of mature and gravid sections of Hymenolepis microstoma, 5-adenyl-imidodiphosphate was used as a substrate, and lead was used as a capturing agent. Results indicate that adenyl cyclase activity is present in the crypts between the microtriches of the mature sections and that activity is absent from the gravid sections.     

Moniezia expansa: the interproglottidal glands and their secretions

Acetylcholinesterase (EC 3:1:1:7) and alkaline phosphatase (EC 3:1:3:1) were detected in secretions of Moniezia expansa maintained in vitro. Ultrastructural cytochemical studies demonstrated acetylcholinesterase activity on the surface of the microtriches at the base of the interproglittidal glands and in the gland lumen but not in the distal tegument or the gland cells. Alkaline phosphatase activity was demonstrated in the cytoplasm of the gland cells and especially in their protoplasmic connections with the distal tegument. Activity was also found in the distal tegument and the microtriches. It is suggested that the acetylcholinesterase secreted by M. expansa performs a metabolic role at the worm's surface.     

Isoparorchis hypselobagri: ultrastructure of the tegument and associated tissues in a digenean inhabiting a gaseous aerobic environment

Adult I. hypselobagri live in the swim bladder of the Indian catfish Wallago attu, a gaseous environment with a relatively high oxygen content. The ventral tegument, which in life is applied close to the swim bladder wall, is relatively unspecialized, showing typical ultrastructural features of the digenean surface. The dorsal tegument, which is exposed to the oxygen-rich surroundings, has numerous pyriform extensions of superficial parenchymal cells closely applied to the base of the surface syncytium. These extensions bear numerous mitochondria and send finger-like processes deep into the basal cytoplasm of the syncytium where they interdigitate with corresponding infolds of the basal tegument membrane. The pyriform parenchymal extensions are connected with underlying nucleated cell bodies via irregular glycogen-filled tubular processes, many of which end blindly in the interstitial tissue or expand into glycogen-filled bulbs beneath the cell bodies. These superficial parenchymal processes associate at gap junctions with ramifications of a distinct deeper parenchymal tissue which contains lipid, residual bodies and glycogen. The dorsal tegument and associated structures may constitute a respiratory organ, taking advantage of molecular oxygen diffusing across the surface syncytium to carry out aerobic energy transduction in the superficial parenchymal extensions. ATP so generated may diffuse inwards for distribution throughout the body in the deep parenchymal tissue. The extensive network of ramifying cytoplasmic tubules is supported by a fibrous matrix of interstitial tissue.     

七星瓢虫成虫对枸杞木虱的捕食作用

为了测定七星瓢虫成虫对枸杞木虱4种虫态的捕食作用,分别在室内测定七星瓢虫的捕食功能反应、种内干扰、自身密度干扰、捕食偏好性以及在田间七星瓢虫对枸杞木虱的捕食效果.结果表明: 七星瓢虫对枸杞木虱的捕食功能反应符合Holling Ⅱ型方程,其中对卵的最大捕食量为112.6粒,对1～2龄若虫、3～5龄若虫、成虫的最大捕食量分别为536、415和113.9头;田间罩笼试验结果证明,七星瓢虫成虫在其生长周期30 d内能使枸杞木虱总虫口密度下降80.1%;七星瓢虫对1～2龄枸杞木虱若虫的搜寻效率参数a=0.9451,处理时间参数T_h=0.001865,整体优于卵、3～5龄若虫与成虫,且在每皿100头的猎物密度下七星瓢虫的最大捕食率能达80.2%,益害比参考值为1∶100.七星瓢虫对枸杞木虱的捕食作用受自身密度的影响显著大于种内干扰.在混合猎物密度为每皿100头下,七星瓢虫更偏好木虱成虫,在密度为每皿300头下,七星瓢虫更偏向于木虱若虫.表明七星瓢虫是很有控制潜力的捕食性天敌,人工释放七星瓢虫成虫可有效取食枸杞木虱初孵若虫,降低木虱为害.     

Successive reduction of the last instar larva of Loricifera, as evidenced by two new species of Pliciloricus from the Great Meteor Seamount (Atlantic Ocean)

Two new species of the genus Pliciloricus Higgins & Kristensen, 1986, are described from coarse sand at the plateau of the Great Meteor Seamount. Together with other species of the genus, Pliciloricus corvus sp. n. and Pliciloricus senicirrus sp. n., demonstrate that the last or seventh instar Higgins-larva can be more and more reduced.

Additionally, in the life cycle of P. corvus sp. n. a simplified adult is discovered which has a simplified body with persisting neck region and a sack-like trunk. The adult of P. corvus sp. n. is characterized, e.g., by 15 broad cross-walls in the clavoscalids, midventral spinoscalids of the second row transformed into a new type of double-organ, a secondary double-organ in the third row of scalids, type B spinoscalids of the fourth row ending in a grappling hook, a crescent-shaped ornamentation of the lorica margin with rounded gaps and protrusions, and a pair of longitudinal cuticular protrusions on the end cone. Distinguishing features of the first to sixth instar Higgins-larvae of P. corvus sp. n. are, e.g., setae of moderate length and long end spines of toes with double bulges. The seventh instar Higgins-larva of P. corvus sp. n. is not fully developed, e.g., the abdominal region is indistinct; the scalids, toes, and all five pairs of setae are clearly shorter than in the preceding instars of Higgins-larvae.

The adult of P. senicirrus sp. n. is characterized, e.g., by clavoscalids with many fine transversal striae, claw-like type B spinoscalids of the fourth row ventrally winged and with seven embedded needle-like teeth, edge of the lorica with 24 small protrusions, and 20 papillate flosculi at caudal end. The Higgins-larva of P. senicirrus sp. n. is characterized, e.g., by the wide and frill-like first section of the mouth cone, the second segment of spinoscalids with ventral serration and double tip, long anterosetae with strong spinules, and by the toes being nearly as long as the short lorica, to name a few. The most obvious feature is the extreme length of the three pairs of posterosetae. The posteroterminal setae are nearly as long as the whole body. The seventh instar Higgins-larva of P. senicirrus sp. n. is not reduced as in the case of P. corvus sp. n.     

扩张莫尼茨绦虫(圆叶目:裸头科)节间腺的超微结构及组织化学

用光学显微镜和透射电子显微镜观察了扩张莫尼茨绦虫节间腺形成过程的精细结构及一些组化变化。结果表明：节间腺是扩张莫尼茨绦虫皮层的特化部分,由节片后缘的皮层及其邻近细胞体向绦虫实质组织中陷入开始其形成过程,随着虫体发育的进行,新的陷入不断形成,原陷入的部分不断脱离皮层形成簇状腺体结构。节间腺的数目随着体节的发育不断增加,幼节中仅有少数几个(6～9个),而远端的孕节中多于100个。电镜下可见腺细胞体由细胞质管与腺皮层相联,簇状腺体结构为一合胞体形态,腺细胞体围绕并开口于椭球体或不规则形状的皮层腔中。离腺皮层远的腺细胞体电子密度高并含有与腺皮层相应的典型分泌颗粒,而靠近腺皮层的腺细胞体电子密度低,所含分泌颗粒较少。扩张莫尼茨绦虫节间腺的组化性质尚不完全清楚。糖与蛋白质等组化结果不稳定,随染液pH值及染色时间的变化等多种因素而改变。基于我们的研究及其他研究者的观察表明,节间腺可能参与外源基质形成虫卵的转运,同时他们可能在虫体节片脱落及虫卵溢出时起作用。