Molecular cloning of the gene for p85 that regulates the initiation of cytokinesis in Tetrahymena.

Tetrahymena p85 is localized to the presumptive division plane before division furrow formation; its molecular weight in SDS-polyacrylamide gel electrophoresis differs in wild-type and temperature-sensitive cell-division-arrest mutant cdaA1 cells. At the restrictive temperature, p85 localization and division furrow formation are not observed in cdaA1 cells. In this study, we purified p85 and cloned a wild-type p85 cDNA. The deduced amino acid sequence of p85 was composed mainly of two kinds of repeat sequences. One of these contained regions homologous to a calmodulin-binding site and a part of actin, and the other contained a region homologous to a part of a cdc2 kinase homologue. Moreover, we cloned a cDNA encoding the cdaA1 p85. There was no difference in the predicted amino acid sequences of wild-type and cdaA1 p85, suggesting that the difference in molecular weight between p85 in wild-type and mutant cells is caused by a disorder of posttranslational-modification mechanisms of p85 in the cdaA1 cell.     

Development of the ciliature of Tetrahymena thermophila: II. Spatial subdivision prior to cytokinesis

The cell surface of Tetrahymena thermophila is made up of an anterior region in which virtually all basal bodies of ciliary rows are ciliated, and the remainder in which ciliated and unciliated basal bodies are fairly irregularly interspersed. This pattern persists through interfission development until the stage of appearance of the equatorial ring of gaps in the ciliary rows that marks the fission zone. The ciliation pattern then becomes subdivided, in large part through the rapid ciliation of contiguous basal bodies located posterior to the fission zone. We interpret this process as a wave of ciliation of preexisting basal bodies that propagates posteriorly from the site of the fission zone. The location, extent, and timing of the ciliation process are the same in inverted as in normally oriented ciliary rows, in spite of the fact that in inverted rows the visible fission zone gap is tardily formed and the local configuration of ciliature around this gap is abnormal. The putative ciliation wave thus does not depend directly upon the local manifestations of the fission zone. However, in a cell-division-arrest mutant, cdaA1, analyzed under conditions in which formation of fission-zone gaps is permanently prevented in some ciliary rows but not in all, it is found that the ciliation pattern becomes subdivided in those ciliary rows that express fission-zone gaps and fails to become subdivided in neighboring rows that fail to manifest gaps. We interpret this combination of findings to indicate that a signal localized at the cell equator initiates a set of polarized developmental events that simultaneously create and demarcate two cellular fields within what was previously one. We further suggest that the characteristic tandem cell division pattern of ciliates is fundamentally a process of segmentation, which might involve mechanisms of gradient subdivision analogous to those taking place during segmentation of insects and other multicellular organisms.     

The influence of fission line expression on the number and positioning of oral primordia in the cdaA1 mutant of Tetrahymena thermophila.

During cytokinesis, furrowing creates new boundaries for daughter cells. Following a shift to a restrictive temperature, cells of the temperature-sensitive cell-division-arrest (cdaA1) mutant of Tetrahymena thermophila complete development of the oral apparatus for the prospective posterior daughter cell before becoming arrested in cytokinesis. When maintained under weak restrictive conditions (35 degrees C), some of the chains were arrested prior to the start of fission line formation (D-shaped chains), whereas others manifested rudimentary unilateral furrowing on the ventral side (B-shaped chains). In their second cell cycle following the temperature shift, the D-shaped chains usually formed only one oral primordium, at a position highly correlated with the length of the entire chain. The B-shaped chains always produced two separate oral primordia, located at irregular positions anterior and posterior to the division furrow, often close to the posterior oral apparatus produced during the first cycle. These results suggest that the formation of the fission line sets a reference boundary to assess the number of oral primordia and influence their position, that appear during subsequent morphogenetic episodes. They also indicate that, during cell division cycles, pre-existing oral apparatuses do not strongly inhibit the formation of new oral apparatuses in their close vicinity.     

The influence of fission line expression on the number and positioning of oral primordia in the cdaA1 mutant of Tetrahymena thermophila

During cytokinesis, furrowing creates new boundaries for daughter cells. Following a shift to a restrictive temperature, cells of the temperature-sensitive cell-division-arrest (cdaA1) mutant of Tetrahymena thermophila complete development of the oral apparatus for the prospective posterior daughter cell before becoming arrested in cytokinesis. When maintained under weak restrictive conditions (35°C), some of the chains were arrested prior to the start of fission line formation (D-shaped chains), whereas others manifested rudimentary unilateral furrowing on the ventral side (B-shaped chains). In their second cell cycle following the temperature shift, the D-shaped chains usually formed only one oral primordium, at a position highly correlated with the length of the entire chain. The B-shaped chains always produced two separate oral primordia, located at irregular positions anterior and posterior to the division furrow, often close to the posterior oral apparatus produced during the first cycle. These results suggest that the formation of the fission line sets a reference boundary to assess the number of oral primordia and influence their position, that appear during subsequent morphogenetic episodes. They also indicate that, during cell division cycles, pre-existing oral apparatuses do not strongly inhibit the formation of new oral apparatuses in their close vicinity. © 1992 Wiley-Liss, Inc.     

The filaments supporting ciliary primordia and fission furrow in the hypotrich ciliateParaurostyla weissei, revealed by the monoclonal antibody 12G9: Studies on wild-type and ciliary hypertrophy mutant

Summary The unique monoclonal antibody FXXXIX 12G9 obtained againstTetrahymena cortices was used to label cytoskeletal structures related to basal body proliferation inParaurostyla weissei. The antibody binds to an amorphous material interconnecting basal bodies in compound ciliary structures: dorsal units, cirri and membranelles in interfission cells, and filamentous structures supporting the primordia of ciliary structures and fission line in dividing cells. The antibody visualized meridional filaments preceding proliferation of new basal bodies in the oral primordium and structures accompanying all developing ciliary primordia. It congregated in differentiating new procirri and membranelles, whereas another population of transient meridional structures accompanied the final distribution of new structures. A meridional filament connecting transverse cirri with the oral apparatus, marking the future stomatogenic meridian, persisted in both division products until completion of cell elongation. The fission line was found to originate from an anterior extension of the pre-oral filament toward the parental oral structures. It then encircled the cell's midbody demarcating the boundary between daughter cells; two additional circumferential structures bordering the anterior and posterior ends of differentiating division products participate in formation of the new poles. They disappear after separation of daughter cells and completion of resorption of parental ciliature. In the enhanced multi-left-marginal mutant expressing gross hyperduplication of basal bodies, the location of the 12G9 antigen corresponded to that in wild-type cells. The sequence of formation of meridional filaments in the mutant was found to be altered. The filaments in the left lateral domain preceded the formation of the preoral filament, yet the temporal pattern of basal body assembly was not modified. The fission line, as in wild-type cells, originated in connection with the oral primordium. We conclude that the nucleation of the filamentous structures bearing the 12G9 antigen and the basal body assembly occur by independent mechanisms reading the same cell cycle signals. We suggest that the 12G9-antigen-bearing protein might be similar to septins: involved in signaling the position of the oral primordium and the fission line and functioning in establishing and maintaining the asymmetric cortical domain characteristics.Abbrevations AZM zone of adorai membranelles - bb basal bodies - CC caudal cirri - FC frontal cirri - Fmf frontal meridional filament - FTV the primordia of fronto-ventro-transverse cirri - LD, RD dorsal rows of bristle units - LM, RM left or right marginal cirral row - OA oral apparatus - OP primordium of the adoral membranelles - pLM, pRM primordium of the left or right marginal cirri - pLD, pRD primordia of the left or right dorsal bristle rows - pUM primordium of the undulating membranes - TC transverse cirri - UM undulating membranes - VC ventral cirral rows     

Molecular subdivision of the cortex of dividing Tetrahymena is coupled with the formation of the fission zone.

In contrast to a mitotic-spindle-associated bipolar cytokinesis, the cytokinesis of polarized ciliates is preceded by a reorganization of the cortex into dual metameric patterns for prospective daughter cells and then separated by a transverse fission line. This study concerns relations between the generation of cortical metamery and the formation of the fission line in an amicronuclear (i.e., without mitotic spindle) ciliate, Tetrahymena pyriformis. The fission line appears in the division of T. pyriformis as a transverse line formed by equatorial gaps in the meridional ciliary rows, with the second oral structure (OA2) formed posterior to it. It was found that the metamery of cortical morphogenesis is expressed by the appearance of increased MPM2 antibody binding in dividing cells in an apical area and posterior to the fission line gaps, including patterned changes of this binding in both oral apparatuses (OA1 and OA2), and by a reciprocal decrease of binding of an anti-epiplasm antibody. These tested antigens are localized to different cortical structures, but in predividing cells both uniformly show formation of the fission line contrast of labeling. A serine/threonine kinase inhibitor, 6-dimethylaminopurine (6-DMAP), was applied to dividing T. pyriformis at specific stages: (1) if 6-DMAP was added to early dividing cells, it prevented cells from initiating cytokinesis. (2) If 6-DMAP was added to cells at stages close to the physiological transition point of cell division, it yielded either (i) a partial formation of the fission line on the ventral side, combined with modified growth of undivided cortex adjacent to the fission line, with abnormal cytokinesis, or (ii) variable anterior displacement of the complete fission line, which contracted slowly but uniformly. (3) If 6-DMAP was applied during cytokinesis, it did not delay cell division, but daughter cells become abnormal and underwent an incomplete oral reorganization. These results suggest that the generation of metamerism in the cortex of T. pyriformis involves differentiation of the asymmetric fission zone. At least four stage-dependent 6-DMAP-sensitive effects jointly control the progress of cell division and the mutual spatial relations between the generation of metamery and the appearance, completeness, and position of the fission zone in the cortex of polarized T. pyriformis.     

Effect of alteration in the global body plan on the deployment of morphogenesis-related protein epitopes labeled by the monoclonal antibody 12G9 in Tetrahymena thermophila

We have employed monoclonal antibodies to reinvestigate the janus mutants of the ciliate Tetrahymena thermophila, which cause reversal of circumferential polarity on the dorsal surface of the cell. This reversal brings about frequent ectopic expression of ventral cortical landmarks, such as a "secondary" oral apparatus, on the dorsal surface. The principal antibody employed, FXXXIX-12G9, immunolabels both transient cortical structures not directly associated with basal bodies (the fission line and the postoral meridional filament) and more permanent structures (apical band and oral crescent) that are associated with basal bodies. 12G9-immunolabeling of janus cells has revealed additional phenotypes, including disorder of ciliary rows. Further, this labeling has shown that the postoral meridional filament is often expressed and the apical band is frequently interrupted on the mid-dorsal surface of janus cells irrespective of whether or not these cells express a "secondary" oral apparatus. Of the permanent structures revealed by 12G9 immunofluorescence, modifications of the oral crescent (OC) are associated with prior modifications in the development of basal body-containing structures in the secondary oral apparatus. The formation of the apical band (AB) is also commonly abnormal in janus cells; analysis of specific abnormalities shows that the AB depends both on its initiation at a specific site near the anterior basal body of apical basal body couplets and on the normal location of these couplets just posterior to the fission line. We also have uncovered an intriguing difference in the reactivity of apical-band filaments to the 12G9 antibody in the two non-allelic janus mutants (janA1 and janC2) that we have investigated. Taken together, our observations indicate that the formation of new cellular structures at division depends both upon pre-existing cytoskeletal structures and upon the positional information provided by large-scale cellular polarities.     

Relationship Between Spatial Pattern of Basal Bodies and Membrane Skeleton (Epiplasm) During the Cell Cycle of Tetrahymena: cdaA Mutant and Anti-Membrane Skeleton Immunostaining

Microtubular basal bodies and epiplasm (membrane skeleton) are the main components of the cortical skeleton of Tetrahymena. The aim of this report was to study functional interactions of basal bodies and epiplasm during the cell cycle. The cortex of Tetrahymena cells was stained with anti-epiplasm antibody. This staining produced a bright epiplasmic layer with a dark pattern of unstained microtubular structures. The fluorescence of the anti-epiplasm antibody disappeared at sites of newly formed microtubular structures, so the new basal body domains and epiplasmic layer could be followed throughout the cell cycle. Different patterns of deployment of new basal bodies were observed in early and advanced dividers. In advanced dividers the fluorescence of the epiplasmic layer diminished locally within the forming fission line where the polymerization of new basal bodies largely extincted. In wild type Tetrahymena, the completion of the micronuclear metaphase/anaphase transition was associated with a transition from the pattern of new basal body deployment and epiplasm staining of the early divider to the pattern of the advanced dividers. The signal for the fission line formation in Tetrahymena (absent in cdaA1 Tetrahymena mutationally arrested in cytokinesis) brings about 1) transition of patterns of deployment of basal bodies and epiplasmic layer on both sides of the fission line; and 2) coordination of cortical divisional morphogenesis with the micronuclear mitotic cycle.     

Fission yeast cells undergo nuclear division in the absence of spindle microtubules

Mitosis in eukaryotic cells employs spindle microtubules to drive accurate chromosome segregation at cell division. Cells lacking spindle microtubules arrest in mitosis due to a spindle checkpoint that delays mitotic progression until all chromosomes have achieved stable bipolar attachment to spindle microtubules. In fission yeast, mitosis occurs within an intact nuclear membrane with the mitotic spindle elongating between the spindle pole bodies. We show here that in fission yeast interference with mitotic spindle formation delays mitosis only briefly and cells proceed to an unusual nuclear division process we term nuclear fission, during which cells perform some chromosome segregation and efficiently enter S-phase of the next cell cycle. Nuclear fission is blocked if spindle pole body maturation or sister chromatid separation cannot take place or if actin polymerization is inhibited. We suggest that this process exhibits vestiges of a primitive nuclear division process independent of spindle microtubules, possibly reflecting an evolutionary intermediate state between bacterial and Archeal chromosome segregation where the nucleoid divides without a spindle and a microtubule spindle-based eukaryotic mitosis.     

Timing of formation of Tetrahymena contractile ring microfilaments investigated by inhibition with skeletal muscle actin

Understanding the mechanism that determines the cell division plane is one of the most important problems in the fields of cell and developmental biology. Studying the timing and site of formation of contractile ring (CR) micro-filaments provides key information for solving the problem. We tried to create a nonfunctional CR in Tetrahymena by microinjecting rabbit skeletal muscle actin, which can copolymerize with Tetrahymena actin but has properties different from those of Tetrahymena actin. When skeletal muscle actin was injected in a predivision stage, before the onset of furrow constriction, long-term arrest of cell division was observed. Muscle actin did not cause any delay in cell division when the actin was injected at any stage other than the predivision stage. In all cases, muscle actin had little affect on other actin-related functions. Injected skeletal muscle actin polymerized near the equatorial division plane in cases of cell division arrest; it polymerized at other nonspecific locations when cell division was observed. Arrest occurred when the microinjection took place in the 17-min period just before the start of furrowing. This period coincides with the occurrence of equatorial deposits of p85, which is also suggested to be required for the determination of the division plane. The present experimental results are consistent with the idea that p85 is a crucial factor for determining the cell division plane and also functions as a polymerization nucleus for CR microfilaments. © 1992 Wiley-Liss, Inc.     

Cell division and the production of cells lacking nuclear bodies in a mutant of Salmonella typhimurium

Summary There are two distinct division phases when the temperature-sensitive DNA synthesis initiation mutant Salmonella typhimurium strain 11G is shifted from 25° to 38°. The first phase appears to represent segregation of the nuclear bodies formed at 38°. Division in this phase takes place at the normal size and produces mainly organisms with one nuclear body. It is dependent on the termination of the rounds of replication in operation at the time of the temperature shift and sensitive to low doses of penicillin. This division phase continues for 60–75 min and then after a short lag division restarts. At first the cells undergoing the second division phase are only slightly larger than normal but they soon grow into short filaments which bud off cells at both ends even if only one nuclear body is present. The cells budded off in this division phase are about 3 long on both broth and M M. They lack nuclear bodies but have a small amount of DNA which may be exclusively in the form of a large plasmid. This second division phase is also dependent on rounds of replication being allowed to terminate at 38° and is sensitive to low levels of penicillin. It is 80–90 min after the temperature shift before the second division phase starts and this lag is maintained even if rounds of replication have been completed prior to the temperature shift by amino acid starvation at 25°. The occurrence of this lag and the demonstration (using penicillin) of potential division sites at regular intervals along 11G filaments suggest that division is initiated some time before the actual division event.     

Studies in fission yeast on mechanisms of cell division site placement

One fundamental problem in cytokinesis is how the plane of cell division is established. In this review, we describe our studies on searching for "signals" that position the cell division plane, using fission yeast Schizosaccharomyces pombe. First, we take a genetic approach to determine how the nucleus may position the contractile ring in fission yeast. mid1p appears to link the position of the ring with the nuclear position, as it is required for proper placement of the contractile ring and is localized in a band at the cell surface overlying the nucleus. Second, we study how microtubules may function in the establishment of cell polarity at the cell tips. tea1p may be deposited on the cell surface by microtubules and function to recruit proteins involved in making actin structures. These studies suggest how microtubules may direct the assembly of the contractile ring in animal cells.     

MORPHOLOGY AND LIFE CYCLE EVENTS IN PYROPHACUS STEINII (SCHILLER) WALL ET DALE (DINOPHYCEAE)

Cells of Pyrophacus steinii (Schiller) Wall et Dale are round and lens shaped and have an anteroposteriorly compressed theca. The epitheca has a truncated, conical horn and a hexagonally shaped apical pore plate with two arched slits positioned off center. The cingulum is equatorial, narrow, and deep. The hypotheca is flat. The sulcus is narrow, slightly curved, and recessed and does not reach the cell's antapex. The plate formula in these specimens of P. steinii is Po, 8', Oa, 13", 13C, 12"', 3p, 3"", and 8S with a difference in the number of precingular (13") and postcingular (12"') plates. No additional posterior intercalary plates were present (Oap). Pregametic stages of P. steinii were observed during cell division via binary fission, with formation of two cells and multiple division with formation of four and eight cells. These newly formed cells were pale in color and were enclosed in double-layered hyaline membrane. Gametes with gymnodinoid morphology were observed within the parental cells. Planozygotes are large and round and enclosed in double-layered hyaline membrane. Mature cell forms are brown with a microgranular cytoplasm, storage bodies, and a red accumulation body. The hypnozygote exhibits triple-layered hyaline membrane, irregularly shaped and comparable with bulbous processes of Tuberculodinium vancampoae Rossigol resting cysts. Division within a hypnocyst of P. steinii involves shedding the parental theca and the development and emergence of two daughter cells with the size and morphology of pregametic cells.     

FINE STRUCTURE OF CELL DIVISION IN CHLAMYDOMONAS REINHARDI : Basal Bodies and Microtubules

Cell division in log-phase cultures of the unicellular, biflagellate alga, Chlamydomonas reinhardi, has been studied with the electron microscope. The two basal bodies of the cell replicate prior to cytokinesis; stages in basal body formation are presented. At the time of cell division, the original basal bodies detach from the flagella, and the four basal bodies appear to be involved in the orientation of the plane of the cleavage furrow. Four sets of microtubules participate in cell division. Spindle microtubules are involved in a mitosis that is marked by the presence of an intact nuclear envelope. A band of microtubules arcs over the mitotic nucleus, indicating the future cleavage plane. A third set of microtubules appears between the daughter nuclei at telophase, and microtubules comprising the "cleavage apparatus" radiate from the basal bodies and extend along both sides of the cleavage furrow during cytokinesis. Features of cell division in C. reinhardi are discussed and related to cell division in other organisms. It is proposed that microtubules participate in the formation of the cleavage furrow in C. reinhardi.     

The spindle pole bodies facilitate nuclear envelope division during closed mitosis in fission yeast

Many organisms divide chromosomes within the confines of the nuclear envelope (NE) in a process known as closed mitosis. Thus, they must ensure coordination between segregation of the genetic material and division of the NE itself. Although many years of work have led to a reasonably clear understanding of mitotic spindle function in chromosome segregation, the NE division mechanism remains obscure. Here, we show that fission yeast cells overexpressing the transforming acid coiled coil (TACC)-related protein, Mia1p/Alp7p, failed to separate the spindle pole bodies (SPBs) at the onset of mitosis, but could assemble acentrosomal bipolar and antiparallel spindle structures. Most of these cells arrested in anaphase with fully extended spindles and nonsegregated chromosomes. Spindle poles that lacked the SPBs did not lead the division of the NE during spindle elongation, but deformed it, trapping the chromosomes within. When the SPBs were severed by laser microsurgery in wild-type cells, we observed analogous deformations of the NE by elongating spindle remnants, resulting in NE division failure. Analysis of dis1Δ cells that elongate spindles despite unattached kinetochores indicated that the SPBs were required for maintaining nuclear shape at anaphase onset. Strikingly, when the NE was disassembled by utilizing a temperature-sensitive allele of the Ran GEF, Pim1p, the abnormal spindles induced by Mia1p overexpression were capable of segregating sister chromatids to daughter cells, suggesting that the failure to divide the NE prevents chromosome partitioning. Our results imply that the SPBs preclude deformation of the NE during spindle elongation and thus serve as specialized structures enabling nuclear division during closed mitosis in fission yeast.     

Causal relations among cell cycle processes in Tetrahymena pyriformis. An analysis employing temperature-sensitive mutants

Utilization of temperature-sensitive mutants of Tetrahymena pyriformis affected in cell division or developmental pathway selection has permitted elucidation of causal dependencies interrelating micronuclear and macronuclear replication and division, oral development, and cytokinesis. In those mutants in which cell division is specifically blocked at restrictive temperatures, micronuclear division proceeds with somewhat accelerated periodicity but maintains normal coupling to predivision oral development. Macronuclear division is almost totally suppressed in an early acting mutant (mola) that prevents formation of the fission zone, and is variably affected in other mutants (such as mo3) that allow the fission zone to form but arrest constriction. However, macronuclear DNA synthesis can proceed for about four cycles in the nondividing mutant cells. A second class of mutants (psm) undergoes a switch of developmental pathway such that cells fail to enter division but instead repeatedly carry out an unusual type of oral replacement while growing in nutrient medium at the restrictive temperature. Under these circumstances no nuclei divide, yet macronuclear DNA accumulation continues. These results suggest that (a) macronuclear division is stringently affected by restriction of cell division, (b) micronuclear division and replication can continue in cells that are undergoing the type of oral development that is characteristic of division cycles, and (c) macronuclear DNA synthesis can continue in growing cells regardless of their developmental status. The observed relationships among events are consistent with the further suggestion that the cell cycle in this organism may consist of separate clusters of events. with a varying degree of coupling among clusters. A minimal model of the Tetrahymena cell cycle that takes these phenomena into account is suggested.     

Microtubule nucleation at non-spindle pole body microtubule-organizing centers requires fission yeast centrosomin-related protein mod20p

BACKGROUND: Many types of differentiated eukaryotic cells display microtubule distributions consistent with nucleation from noncentrosomal intracellular microtubule organizing centers (MTOCs), although such structures remain poorly characterized. In fission yeast, two types of MTOCs exist in addition to the spindle pole body, the yeast centrosome equivalent. These are the equatorial MTOC, which nucleates microtubules from the cell division site at the end of mitosis, and interphase MTOCs, which nucleate microtubules from multiple sites near the cell nucleus during interphase. RESULTS: From an insertional mutagenesis screen we identified a novel gene, mod20+, which is required for microtubule nucleation from non-spindle pole body MTOCs in fission yeast. Mod20p is not required for intranuclear mitotic spindle assembly, although it is required for cytoplasmic astral microtubule growth during mitosis. Mod20p localizes to MTOCs throughout the cell cycle and is also dynamically distributed along microtubules themselves. We find that mod20p is required for the localization of components of the gamma-tubulin complex to non-spindle pole body MTOCs and physically interacts with the gamma-tubulin complex in vivo. Database searches reveal a family of eukaryotic proteins distantly related to mod20p; these are found in organisms ranging from fungi to mammals and include Drosophila centrosomin. CONCLUSIONS: Mod20p appears to act by recruiting components of the gamma-tubulin complex to non-spindle pole body MTOCs. The identification of mod20p-related proteins in higher eukaryotes suggests that this may represent a general mechanism for the organization of noncentrosomal MTOCs in eukaryotic cells.     

Dynamin-like protein-dependent formation of Woronin bodies in Saccharomyces cerevisiae upon heterologous expression of a single protein

Filamentous ascomycetes harbor Woronin bodies and glyoxysomes, two types of microbodies, within one cell at the same time. The dominant protein of the Neurospora crassa Woronin body, HEX1, forms a hexagonal core crystal via oligomerization and evidence has accumulated that Woronin bodies bud off from glyoxysomes. We analyzed whether HEX1 is sufficient to induce Woronin body formation upon heterologous expression in Saccharomyces cerevisiae, an organism devoid of this specialized organelle. In wild-type strain BY4742, initial import of HEX1 into existing peroxisomes enabled the formation of organelles with a hexagonal crystal. The observed structures mimicked the shape of genuine Woronin bodies, but exhibited a lower density and were significantly larger. Double-immunofluorescence analysis revealed that hexagonal HEX1 structures only occasionally co-localized with peroxisomal marker proteins, indicating that the Woronin-body-like structures are well separated from peroxisomes. In cells lacking Vps1p and Dnm1p, dynamin-like proteins required for the division of peroxisomes, the Woronin-body-like organelles remained attached to peroxisomes. The data indicate that Woronin bodies emerge after the formation of a HEX1 core crystal within peroxisomes followed by Vps1p- and Dnm1p-mediated fission.     

Sid2p, a spindle pole body kinase that regulates the onset of cytokinesis.

The fission yeast Schizosaccharomyces pombe divides by medial fission through the use of an actomyosin contractile ring. Precisely at the end of anaphase, the ring begins to constrict and the septum forms. Proper coordination of cell division with mitosis is crucial to ensure proper segregation of chromosomes to daughter cells. The Sid2p kinase is one of several proteins that function as part of a novel signaling pathway required for initiation of medial ring constriction and septation. Here, we show that Sid2p is a component of the spindle pole body at all stages of the cell cycle and localizes transiently to the cell division site during medial ring constriction and septation. A medial ring and an intact microtubule cytoskeleton are required for the localization of Sid2p to the division site. We have established an in vitro assay for measuring Sid2p kinase activity, and found that Sid2p kinase activity peaks during medial ring constriction and septation. Both Sid2p localization to the division site and activity depend on the function of all of the other septation initiation genes: cdc7, cdc11, cdc14, sid1, spg1, and sid4. Thus, Sid2p, a component of the spindle pole body, by virtue of its transient localization to the division site, appears to determine the timing of ring constriction and septum delivery in response to activating signals from other Sid gene products.     

Assembly and fate of basal bodies in the colourless phytoflagellate Polytoma papillatum

Summary— The morphogenesis of basal bodies is described in the phytoflagellate Polytoma papillatum. The observations are based on the analysis of ultrathin serial sections through the flagellar apparatus of interphase, mitotic, and postmitotic cells using transmission electron microscopy. Formation of new basal bodies starts in prometaphase. Individual A-subfibres develop orthogonally to the long axis of mature basal bodies. The microtubules assemble at the surface of an annulus of amorphous material. By telophase, a complete cylinder of A-subfibres with a length of approximately 300 nm has formed. Although the proximal ends of these new probasal bodies are detached from the mature basal bodies, prominent reorientation of the probasal bodies does not occur. They remain with their proximal ends in the vicinity of mature basal bodies. In daughter cells with probasal bodies around 400 nm long, the assembly of microtubular triplets is initiated. B- and C-subfibres first show up distal from the mature basal bodies and may elongate towards them. Thus, A-subfibres on the one side and B- and C-subfibres on the other appear to growt with opposite polarity. If A-subfibres grow at their plus ends, B- and C-subfibres elongate at their minus ends. The latter is unusual in comparison with individual cytoplasmic and spindle microtubules. Possible the presence of a lateral template in the form of the A-subfibres is responsible for the deviating growth characteristics of the incomplete B- and C-subfibres. In interphase cells, the mature basal bodies extend into long flagella. The new basal bodies remain devoid of flagella and are less than 85 nm long. Thus, they have shortened relative to their precursors in mitotic and postmitotic cells. At the onset of a new division cycle, the flagellate basal badies shed their flagella. The breaking point is at the triplet-doublet transition of the flagellum.