Oogenesis in the honeybee Apis mellifera: cytological observations on the formation and differentiation of previtellogenic ovarian follicles

Summary Oogenesis is known to be important for embryonic pattern formation. For this reason we have studied the early differentiation of the honeybee ovariole histologically, ultrastructurally, and by staining F-actin with rhodaminyl-phalloidin. At the anterior tip of the ovariole, stem cells are lined up in a single file; they are organelle-poor but contain characteristic electrondense bodies with lysosomal properties. The presence of these bodies in cystocytes as well as prefollicle cells indicates that both cell types may be derived from the apical stem cells. During later stages of oogenesis, the follicle cells differentiate cytologically in different regions of the follicle. The organization of the intercellular bridges between cystocytes derived from a single cystoblast has been studied in detail. The polyfusomes in the intercellular bridges of cystocyte clusters stain with rhodaminyl-phalloidin and hence contain F-actin. Later, when the polyfusomes begin to desintegrate, F-actin rings form which line the rims of the intercellular bridges. Actin might be recruited from conspicuous F-actin stores which were detected in the germ-line cells. The F-actin rings are dissembled some time before the onset of vitellogenesis when the nurse chamber has grown to a length of about 200 m. At the basal side of the follicle cells (close to the basement membrane facing the haemocdele) parallel microfilament bundles encircle the ovariole. The microfilament bundles which are oriented mostly perpendicular to the long axis of the ovariole were first observed around the zone where the cystocyte divisions occur; after this phase the micro-filament bundles become organized differently in the follicle cells associated with the nurse cells and in the follicular epithelium of the oocyte. Correspondence to: H.O. Gutzeit     

The linear clusters of oogonial cells in the development of telotrophic ovarioles in polyphageColeoptera

Summary During the premetamorphic development of coleopteran telotrophic ovaries the culsters of sister oogonial cells, in which the differentiation of nurse cells and oocytes occurs, are arranged in linear chains. This results from a series of mitoses with the consistent orientation of the spindle parallel to the long axis of the ovariole. As a result of incomplete cytokinesis, the oogonial cells in each sibling cluster are linked to each other by intercellular bridges occupied by fusomes. As a rule, at each cluster division the basal cell (i.e. the oocyte progenitor) starts to divide first. From this cell a wave of mitoses spreads toward the anterior end of the cluster, resulting in a mitotic gradient. It is suggested that the failure of the fusomes in adjacent cells to fuse into one continuous fusome (i.e. polyfusome) allows the spindles to orientate with their long axes parallel to the long axis of the sibling cluster. This would explain why the oogonial divisions in coleopteran telotrophic ovaries generate linear chains of cells rather than the cyst-like arrangement which is typical for polytrophic sibling clusters. Dividing sibling clusters within ovarioles are arranged in bundles. The presence of intercellular bridges between sibling clusters seems to be the underlying cause of this nonrandom distribution of the mitotically active clusters. The transverse bridges have been found to occur between the basal cells as well as between the cells located more anteriorly in adjacent sibling clusters. The transverse bridges are filled with typical fusomes, which in more anterior parts of sibling clusters may fuse with the fusomes of adjacent sister oogonial cells into polyfusomes. The transverse bridges between the basal cells are incorporated in the oocytes. The pattern of sibling cluster formation described in this paper apparently occurs widespread in polyphagous Coleoptera, since it has been found in three relatively distantly related families.