Hildebrand H F
Z Parasitenkd. 1980;64(1):29-46. doi: 10.1007/BF00927055.
The fine structure of the epicyte of D. gigantea was investigated. The motility of the gregarine and the contractile elements are described. Four essential types of movements can be observed in this gregarine: (1) rolling up and pendular movements, (2) locomotion by gliding forward, (3) cytoplasmic streaming (Fig. 1), (4) peristaltic contractions (Fig. 2) which seem to be accompanied by the contraction of annular myonemes (Fig. 2). The epicyte is formed by the folding of the parasitic cell wall which is made from three membranes (Figs. 3 and 4). At the top of each fold one can see apical struts between the outer and middle membrane and apical filaments under the inner membrane (Fig. 3). In addition, the epicytic folds are covered by a cell coat which is made from tubular structures (Fig. 5). At the base of the epicytic folds can be observed the basal lamina (Fig. 3) composed of very fine fibrillar material with an average thickness of 2.5 nm (Fig. 6). These fibrils are oriented in the longitudinal axis of the gregarine. Beneath the epicytic fold in the ectoplasm are found the annular myonemes with a width of up to 0.5 micrometers (Fig. 7). They are composed of many fine fibrils with an average thickness of 5 nm. In young trophozoites, the myonemes also contain microtubuli (Fig. 8). Between the epicytic folds, the cell wall is interrupted by three different types of vesicles: the vesicles with an electrondense content (Fig. 9), the three-membranous vesicles (Fig. 10), and the hose-shaped vesicles (Fig. 11). Glycerol-extraction of the parasites was performed in order to define the contractile structures. After extraction the annular myonemes are difficult to recognize (Fig. 13). When ATP is added, the gregarine does not contract but the myonemes reappear after 3 to 4 min (Fig. 14). Differences can also be observed in the myoneme structure using electron microscopy: After extraction, the myonemes are composed of a very limp fibrillar network (Fig. 15) which becomes very dense after the action of ATP (Fig. 16). Glycerol extraction does not disturb either the apical struts and apical filaments or the fibrils of the basal lamina (Figs. 15--17). In addition, cytoplasmic fibrillar structures appear after glycerol extraction (Figs. 15 and 16). The experimental and electron microscope results indicate that the motility of the gregarine depends upon four different systems: (1) the ectoplasmic annular myonemes, (2) the apical structures in the undulating epicytic folds, (3) the cytoplasmic fibrils, and (4) the basal lamina.
对巨大双滴虫的表膜精细结构进行了研究。描述了这种簇虫的运动性和收缩元件。在这种簇虫中可观察到四种基本运动类型:(1)卷曲和钟摆运动,(2)向前滑行运动,(3)细胞质流动(图1),(4)蠕动收缩(图2),这种收缩似乎伴随着环形肌原纤维的收缩(图2)。表膜由寄生细胞壁折叠形成,寄生细胞壁由三层膜构成(图3和图4)。在每个褶皱顶部,可以看到外膜和中膜之间的顶端支柱以及内膜下方的顶端细丝(图3)。此外,表膜褶皱被由管状结构构成的细胞衣覆盖(图5)。在表膜褶皱基部可观察到由非常细的纤维状物质组成的基膜(图3),其平均厚度为2.5纳米(图6)。这些纤维沿簇虫的纵轴排列。在表膜褶皱下方的外质中发现宽度达0.5微米的环形肌原纤维(图7)。它们由许多平均厚度为5纳米的细纤维组成。在年轻的滋养体中,肌原纤维还含有微管(图8)。在表膜褶皱之间,细胞壁被三种不同类型的囊泡中断:含有电子致密内容物的囊泡(图9)、三层膜囊泡(图10)和软管状囊泡(图11)。为了确定收缩结构,对寄生虫进行了甘油提取。提取后,环形肌原纤维很难辨认(图13)。添加ATP后,簇虫不收缩,但3至4分钟后肌原纤维重新出现(图14)。使用电子显微镜也可观察到肌原纤维结构的差异:提取后,肌原纤维由非常松弛的纤维状网络组成(图15),在ATP作用后变得非常致密(图16)。甘油提取不会干扰顶端支柱和顶端细丝或基膜的纤维(图15 - 17)。此外,甘油提取后会出现细胞质纤维状结构(图15和图16)。实验和电子显微镜结果表明,簇虫的运动性取决于四种不同系统:(1)外质环形肌原纤维,(2)起伏表膜褶皱中的顶端结构,(3)细胞质纤维,(4)基膜。
