Centriole maturation in the amoebae ofPhysarum polycephalum

Summary The precise geometry of pro-centriole formation has been studied inPhysarum polycephalum amoebae. The spatial references used were the posterior and the anterior kinetosomes which are unequivocally defined by the presence of the posterior para-kinetosomal structure, the microtubular array 4 and the microtubular arrays 1, 2, and 3. The observations made suggest that pro-centrioles follow a maturation process. A pro-centriole formed during the n^th cell cycle becomes the posterior kinetosome during the (n + 1)^th cell cycle and the anterior one during all the following cell cycles. Pro-centriole formation occurs late in the cell cycle. This observation disagrees with a role of pro-centriole formation in the regulation of S phase in contrast to what has been suggested in other eucaryotic cells.     

Association of centrioles with clusters of apical vesicles in mitotic thyroid epithelial cells. Are centrioles involved in directing secretion?

Summary The ultrastructure of thyroid epithelial cells in mitosis has been investigated. A spatial association is described between clusters of apical vesicles (believed to contain thyroglobulin destined for secretion into the follicular lumen) and centrioles, in late prophase and late telophase cells. Quantitative techniques demonstrate the statistical significance of this association and suggest that it is not related to proximity of the Golgi apparatus or to the location of the centriole in the cell, which changes considerably during these phases of mitosis. The physical basis for this association remains uncertain, but microtubules emanating from the pericentriolar area may be involved.In interphase cells, centrioles are located very close to the follicular lumen, where the majority of apical vesicles are also found. The association of centrioles with clusters of apical vesicles also in mitotic cells suggests that in interphase cells the apically located centrioles may serve as a focus for apical vesicles, helping to direct these secretory vesicles toward the follicular lumen and to maintain cellular polarization. Previous studies demonstrating that centrioles can act as microtubule organizing centers in interphase cells and studies linking microtubules and secretion also tend to support this hypothesis.The author is grateful to Drs. Jan Wolff, Lars E. Ericson, and Seymour H. Wollman for useful discussions and to Mr. Franklin E. Reed for expert technical assistance.     

Close association of centrosomes to the distal ends of the microbody during its growth, division and partitioning in the green alga Klebsormidium flaccidum

Summary. Division and partitioning of microbodies (peroxisomes) of the green alga Klebsormidium flaccidum, whose cells contain a single microbody, were investigated by electron microscopy. In interphase, the rod-shaped microbody is present between the nucleus and the single chloroplast, oriented perpendicular to the pole-to-pole direction of the future spindle. A centriole pair associates with one distal end of the microbody. In prophase, the microbody changes not only in shape, from a rodlike to a branched form, but also in orientation, from perpendicular to parallel to the future pole-to-pole direction. Duplicated centriole pairs are localized in close proximity to both distal ends of the microbody. In metaphase, the elongated microbody flanks the open spindle, with both distal ends close to the centriole pair at either spindle pole. The microbody further elongates in telophase and divides after septum formation (cytokinesis) has started. The association between the centrioles and both distal ends of the microbody is maintained throughout mitosis, resulting in the distal ends of the elongated microbody being fixed at the cellular poles. This configuration of the microbody may be favorable for faithful transmission of the organelle during cell division. After cytokinesis is completed, the microbody reverts to the perpendicular orientation by changing its shape. Microtubules radiating from the centrosomes flank the side of the microbody throughout mitosis. The close association of centrosomes and microtubules with the microbody is discussed in respect to the partitioning of the microbody in this alga. Correspondence: H. Hashimoto, Department of Life Sciences, Graduate School of Arts and Sciences, University of Tokyo, Komaba, Meguro-ku, Tokyo 153-8902, Japan. Present address: M. Honda, Department of Computational Biology, Graduate School of Frontier Sciences, University of Tokyo, Kashiwa, Chiba, Japan.     

Self-assembling SAS-6 Multimer Is a Core Centriole Building Block

Centrioles are conserved microtubule-based organelles with 9-fold symmetry that are essential for cilia and mitotic spindle formation. A conserved structure at the onset of centriole assembly is a “cartwheel” with 9-fold radial symmetry and a central tubule in its core. It remains unclear how the cartwheel is formed. The conserved centriole protein, SAS-6, is a cartwheel component that functions early in centriole formation. Here, combining biochemistry and electron microscopy, we characterize SAS-6 and show that it self-assembles into stable tetramers, which serve as building blocks for the central tubule. These results suggest that SAS-6 self-assembly may be an initial step in the formation of the cartwheel that provides the 9-fold symmetry. Electron microscopy of centrosomes identified 25-nm central tubules with repeating subunits and show that SAS-6 concentrates at the core of the cartwheel. Recombinant and native SAS-6 self-oligomerizes into tetramers with ∼6-nm subunits, and these tetramers are components of the centrosome, suggesting that tetramers are the building blocks of the central tubule. This is further supported by the observation that elevated levels of SAS-6 in Drosophila cells resulted in higher order structures resembling central tubule morphology. Finally, in the presence of embryonic extract, SAS-6 tetramers assembled into high density complexes, providing a starting point for the eventual in vitro reconstruction of centrioles.     

Localization of Golgi 58K protein (formiminotransferase cyclodeaminase) to the centrosome

In vertebrate cells, the centrosome consists of a pair of centrioles and surrounding pericentriolar material. Using anti-Golgi 58K protein antibodies that recognize formiminotransferase cyclodeaminase (FTCD), we investigated its localization to the centrosome in various cultured cells and human oviductal secretory cells by immunohistochemistry. In addition to the Golgi apparatus, FTCD was localized to the centrosome, more abundantly around the mother centriole. The centrosome localization of FTCD continued throughout the cell cycle and was not disrupted after Golgi fragmentation, which was induced by colcemid and brefeldin A. Centriole microtubules are polyglutamylated and stable against tubulin depolymerizing drugs. FTCD in the centrosome may be associated with polyglutamylated residues of centriole microtubules and may play a role in providing centrioles with glutamate produced by cyclodeaminase domains of FTCD.     

Parthenogenesis in non-rodent species: developmental competence and differentiation plasticity

An oocyte can activate its developmental process without the intervention of the male counterpart. This form of reproduction, known as parthenogenesis, occurs spontaneously in a variety of lower organisms, but not in mammals. However, it must be noted that mammalian oocytes can be activated in vitro, mimicking the intracellular calcium wave induced by the spermatozoon at fertilization, which triggers cleavage divisions and embryonic development. The resultant parthenotes are not capable of developing to term and arrest their growth at different stages, depending on the species. It is believed that this arrest is due to genomic imprinting, which causes the repression of genes normally expressed by the paternal allele. Human parthenogenetic embryos have recently been proposed as an alternative, less controversial source of embryonic stem cell lines, based on their inherent inability to form a new individual. However many aspects related to the biology of parthenogenetic embryos and parthenogenetically derived cell lines still need to be elucidated. Limited information is available in particular on the consequences of the lack of centrioles and on the parthenote's ability to assemble a new embryonic centrosome in the absence of the sperm centriole. Indeed, in lower species, successful parthenogenesis largely depends upon the oocyte's ability to regenerate complete and functional centrosomes in the absence of the material supplied by a male gamete, while the control of this event appears to be less stringent in mammalian cells. In an attempt to better elucidate some of these aspects, parthenogenetic cell lines, recently derived in our laboratory, have been characterized for their pluripotency. In vitro and in vivo differentiation plasticity have been assessed, demonstrating the ability of these cells to differentiate into cell types derived from the three germ layers. These results confirmed common features between uni- and bi-parental embryonic stem cells. However data obtained with parthenogenetic cells indicate the presence of an intrinsic deregulation of the mechanisms controlling proliferation vs. differentiation and suggest their uni-parental origin as a possible cause.     

γ-Taxilin temporally regulates centrosome disjunction in a Nek2A-dependent manner

Never in mitosis A-related kinase 2A (Nek2A), a centrosomal serine/threonine kinase, is involved in mitotic progression by regulating the centrosome cycle. Particularly, Nek2A is necessary for dissolution of the intercentriole linkage between the duplicated centrosomes prior to mitosis. Nek2A activity roughly parallels its cell cycle-dependent expression levels, but the precise mechanism regulating its activity remains unclear. In this study, we found that γ-taxilin co-localized with Nek2A at the centrosome during interphase and interacted with Nek2A in yeast two-hybrid and pull-down assays and that γ-taxilin regulated centrosome disjunction in a Nek2A-dependent manner. γ-Taxilin depletion increased the number of cells with striking splitting of centrosomes. The precocious splitting of centrosomes induced by γ-taxilin depletion was attenuated by Nek2A depletion, suggesting that γ-taxilin depletion induces the Nek2A-mediated dissolution of the intercentriole linkage between the duplicated centrosomes nevertheless mitosis does not yet begin. Taken together with the result that γ-taxilin protein expression levels were decreased at the onset of mitosis, we propose that γ-taxilin participates in Nek2A-mediated centrosome disjunction as a negative regulator through its interaction with Nek2A.     

Further studies on the ring canal system of the ovarian cystocytes of Drosophila melanogaster

Summary An ultrastructural study was made of the ring canal system which connects the sister ovarian cystocytes that arise in the germaria of wild type Drosophila melanogaster females. It was discovered that during an oogonial mitosis both chromosomes and spindle are enclosed by a multilayered, perforated membrane system derived (at least in part) from the nuclear envelope. The cytokinesis of stem line oogonia takes place through the formation of a cleavage furrow. A second method of formation of plasma membrane is found in the case of cystocytes. It involves the production along the plane of division of a plaque of interconnected vesicles and tubules and later the coalescence of nearby tubules to form continuous sheets of membrane which segregate the cytoplasms of the sister cells. However, these remain connected by a canal which is enclosed by a ring-shaped rim that is completed prior to the plasma membrane to which the rim is subsequently attached. It is postulated that the rim represents a transformed midbody. As development proceeds the canal becomes wider, its rim becomes thicker, and the inner circumference of the rim becomes coated with a thick deposit having different cytochemical properties than the rim itself. Cystocyte divisions produce sister cells which differ in that one receives all previously formed canals; the other none. In the case of the last division (and perhaps in earlier ones as well) the sister cell receiving all previously formed canals also receives more cytoplasm than its sister. As the cells of the cluster grow, the canals remain close together. This finding suggests that when new plasma membrane is synthesized, it is added in areas remote from the canals. An investigation of the positioning in three dimensions of the fifteen canals of a newly formed, 16 cellcluster suggests that the spindles produced at one division are never parallel to those formed at the subsequent division. This continual shifting of the axes of the spindles at consecutive divisions presumably results in the branching chains of cells which characterize a cystocyte cluster. The possession of a unique pattern of cortical structures by two cystocytes is accompanied by the nuclear synthesis of synaptonemal complexes. The other fourteen cystocytes differentiate into nurse cells. In the most posterior portion of the germarium one of the two potential oocytes switches to the nurse cell developmental pathway. This switched off oocyte and the definitive oocyte grow at rates which differ greatly and are correlated to the amount of contact between their surfaces and certain follicle cells. As development proceeds centrioles accumulate in the oocyte, and most of these are thought to have been carried from the nurse cells into the oocyte in the nutrient stream.The authors are grateful to Richard Z. Belch and James E. Bradof for their conscientious assistance and to E. John Pfiffner for preparation of the inked drawings and construction of the Polyform models. This research was supported by the National Science Foundation grant GB7457.     

The distribution of centrosomes in endothelial cells of non-wounded and wounded aortic organ cultures

Summary The distribution of centrosomes in porcine vascular endothelial cells of the thoracic aorta maintained in organ culture was determined in en face preparations using immunofluorescence. Rectangular pieces of aorta that had the distal half (with respect to the heart) of their endothelial surface gently denuded with a scalpel blade and pieces with intact endothelium were cultured for up to 96 h. At time 0, centrosomes were found to be preferentially oriented toward the heart, both in the cells of intact monolayers and in cells at the wound edge. This distribution was maintained in the intact monolayers for at least 24 h, but by 72 h the number of centrosomes in the center of the cells exceeded the number oriented toward the heart as the cells changed from a fusiform to a polygonal shape. The centrosomes of most endothelial cells at the wound edge began to redistribute themselves within the first 24 h in culture, moving from a position toward the heart to a position either in the center of the cell or away from the heart. By 72 h, the majority of centrosomes in endothelial cells at the wound edge were oriented away from the heart toward the denuded region. It is concluded that the centrosomes in the endothelial cells maintained in organ culture respond to injury in a manner similar to those grown in monolayer cell culture except that the reorientation of centrosomes occurs more slowly.     

Regulation of the paternal inheritance of centrosomes in starfish zygotes

In most animals, fertilized eggs inherit one centrosome from a meiosis-II spindle of oocytes and another centrosome from the sperm. However, since first proposed by Boveri [Sitzungsber. Ges. Morph. Phys. Münch. 3 (1887) 151-164] at the turn of the last century, it has been believed that only the paternal (sperm) centrosome provides the division poles for mitosis in animal zygotes. This uniparental (paternal) inheritance of centrosomes is logically based on the premise that the maternal (egg) centrosome is lost before the onset of the first mitosis. For the processes of the selective loss of the maternal centrosome, three models have been proposed: One stresses the intrinsic factors within the centrosome itself; the other two emphasize external factors such as cytoplasmic conditions or the sperm centrosome. In the present study, we have examined the validity of one of the models in which the sperm centrosome overwhelms the maternal centrosomes. Because centrosomes cast off into both the first and the second polar bodies (PB) are known to retain the capacity for reproduction and cell-division pole formation, we observed the behavior of those PB centrosomes with reproductive capacity and the sperm centrosome in the same zygotic cytoplasm. We prepared two kinds of fertilized eggs that contain reproductive maternal centrosomes, (1) by micromanipulative transplantation of the PB centrosomes into fertilized eggs, and (2) by suppression of the PB extrusions of fertilized eggs with cytochalasin B. In both types of eggs, the PB centrosomes could double and form cell-division poles, indicating that they are not suppressed by the sperm centrosome, which in turn indicates that selective loss of the maternal centrosome is due to intrinsic factors within the centrosomes themselves.