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The development of achrosomes in spermiogenesis of Blattella germanica was studied by electron microscopy. Achrosomes consist of an achrosomal vesicle originating from Golgi vesicles and an axial rod composed of fine fibrils.
The achrosomal vesicle, formed at the mature face of the Golgi body, migrates to the anterior of the nucleus, where it later becomes the front structures of sperm head. After attachment to the nucleus, the achrosomal vesicle changes from a round to a tapering shape, passing through a coneshape phase. During these changes, the axial rod develops in the hollow formed by indentations of adjacent parts of the achrosomal vesicle and the nucleus.
The cisternae of the Golgi body concerned with formation of the achrosomal vesicle, are made by pinching off small vesicles from both the ER and the nuclear envelope. 相似文献
The achrosomal vesicle, formed at the mature face of the Golgi body, migrates to the anterior of the nucleus, where it later becomes the front structures of sperm head. After attachment to the nucleus, the achrosomal vesicle changes from a round to a tapering shape, passing through a coneshape phase. During these changes, the axial rod develops in the hollow formed by indentations of adjacent parts of the achrosomal vesicle and the nucleus.
The cisternae of the Golgi body concerned with formation of the achrosomal vesicle, are made by pinching off small vesicles from both the ER and the nuclear envelope. 相似文献
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The Possible Involvement of Cyclic AMP and Volatile Substance (s) in the Development of a Macrocyst-Forming Strain of Dictyostelium mucoroides 总被引:2,自引:2,他引:0
A mutant MF1 previously isolated from Dictyostelium mucoroides -7 (Dm7) formed macrocysts with or without light when plated on agar at high cell dinsities. At lower cell densities, however, the MF1 cells formed only fruiting bodies. This failure to form macrocysts was shown to be due to the subthreshfold concentration of a volatile substance(s) required for macrocyst formation. Although ammonia is a volatile substance produced by both the Dm7 and MF1 cells, no evidence of its involvement in macrocyst formation was obtained. Mixing the Dm7 and MF1 in a one-to-one ratio resulted only in fruiting body formation suggesting that the Dm7 cells produced a factor which allowed MF1 cells to form fruiting bodies. This factor may be cyclic AMP (cAMP) since addition of cAMP to the medium directed development of MF1 cells to fruiting body formation. The effect of cAMP was exhibited most conspicuously when MF1 cells were exposed at the aggregation stage. Based on these results it is suggested that developmental pathway of the D. mucoroides macrocystforming strain Dm7 and its mutant MF1 may be determined by the relative concentrations of the volatile, macrocyst-inducing substance(s) and cAMP at the aggregation stage. 相似文献
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AIKO SAKAI 《Development, growth & differentiation》1974,16(3):181-190
The origin and the formation of the ascospore delimiting membrane in Sordaria humana were studied by electron microscopy. The complete delimiting membrane consists of a double unit membrane system. It originates from tubular elements of 70–100 nm diameter which are formed with a thin membrane 5–6 nm thick and filled with electron translucent materials. The process of development of the delimiting membrane is as follows: Tubular elements first aggregate, and then become arranged in a plane. Soon afterwards, they fuse laterally and become transformed into a delimiting membrane. Spore delimitation starts from the distal end of the centriolar plaque and develops towards the opposite side of the nucleus, preceding the formation of the membrane system. 相似文献
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