Division Furrow Research Articles

Cytokinesis in Tetrahymena: determination of division plane and organization of contractile ring.

A protein, Tetrahymena p85, is localized to the presumptive division plane before the formation of the contractile ring. p85 directly interacts with Tetrahymena calmodulin (CaM) in a Ca(2+)-dependent manner, and p85 and CaM colocalize in the division furrow. A Ca(2+)/CaM inhibitor N-(6-Aminohexyl)-5-chloro-1-naphthalenesulfonamide HCl (W7) inhibits the direct interaction between p85 and Ca(2+)/CaM. W7 also inhibits the localization of p85 and CaM to the division plane, and the formation of the contractile ring and division furrow. Tetrahymena fimbrin and elongation factor-1a (EF-1alpha), which induce bundling of Tetrahymena F-actin, are also localized to the division furrow during cytokinesis. The Tetrahymena fimbrin has two actin-binding domains, but lacks the EF-hand Ca(2+)-binding motif, suggesting that Tetrahymena fimbrin probably cross-links actin filaments in a Ca(2+)- insensitive manner during cytokinesis. The evidence also indicates that Ca(2+)/CaM inhibits the F-actin-bundling activity of EF-1alpha; and EF-1alpha and CaM colocalize in the division furrow. In this review, we propose that the Ca(2+)/CaM signal and its target protein p85 cooperatively regulate the determination of the division plane, and that a Ca(2+)-insensitive actin-bundling protein, Tetrahymena fimbrin, and a Ca(2+)/CaM-sensitive actin-bundling protein, EF-1alpha, play pivotal roles in regulating the organization of the contractile ring microfilaments.

Cellular growth of host and symbiont in a cnidarian-zooxanthellar symbiosis.

The hydroid Myrionema ambionense, a fast-growing cnidarian (doubling time = 8 days) found in shallow water on tropical back-reefs, lives in symbiosis with symbiotic dinoflagellates of the genus Symbiodinium (hereafter also referred to as zooxanthellae). The symbionts live in vacuoles near the base of host digestive cells, whereas unhealthy looking zooxanthellae are generally located closer to the apical end of the host cell. Cytokinesis of zooxanthellae occurred at night, with a peak in number of symbionts with division furrows (mitotic index, MI = 12%-20%) observed at dawn. The MI of zooxanthellae decreased to near zero by the middle of the afternoon and remained there until the middle of the next night. Densities of live zooxanthellae living inside of host digestive cells peaked following cytokinesis, whereas densities of unhealthy looking symbionts were highest just before the division peak. Mitosis of host digestive cells was highest in the evening, also preceding the peak in zooxanthellar MI. This is the first study relating phased host cell division to diel zooxanthellar division in marine cnidarians. Food vacuoles were prevalent inside of digestive cells of field-collected hydroids within a few hours after sunset and throughout the night, coinciding with digestion of captured demersal plankton. Laboratory experiments showed that food vacuoles appeared in digestive cell cytoplasm within 2 h of feeding with nauplii of Artemia. The number and size of food vacuoles per digestive cell and the percentage of digestive cells with food vacuoles all decreased 5-7 h following feeding in laboratory experiments, and by mid-day in field-collected hydroids. Light and external food supply were important in maintaining phased division of the symbionts, with a lag in response time to both parameters of 11-36 h. Altering light and feeding during the night did not influence the level of the peak MI the next morning, though in one experiment the absence of light slowed final separation of daughter cells at the end of cytokinesis. In another experiment, hydroids starved for 3-7 d and "pulse-fed" Artemia nauplii for 1 h at the beginning of the dark period showed continued low symbiont division (< 5%) after 11 h, whether maintained in constant light or darkness, implying that most algal division is set more than 24 h prior to actual cytokinesis. Transferred to a 14:10 h light:dark cycle for another 24 h (36 h after feeding), the same hydroids exhibited a "normal" peak MI (ca. 15%) at dawn, but zooxanthellae from hydroids kept in constant darkness still showed a low MI. These results show that mitosis of symbiotic dinoflagellates requires three factors: external food; a minimum period of time following feeding (11-36 h), presumably for digestion; and a period of light following feeding, presumably to provide carbon skeletons necessary for completing cytokinesis.

Tetrahymena elongation factor-1 alpha is localized with calmodulin in the division furrow.

Translation elongation factor 1 alpha (EF-1 alpha) catalyzes the GTP-dependent binding of amino-acyl-tRNA to ribosomes. We previously reported that Tetrahymena EF-1 alpha induced the formation of bundles of rabbit skeletal muscle filamentous actin (F-actin) as well as Tetrahymena F-actin [Kurasawa et al. (1996) Zool. Sci. (Tokyo) 13, 371-375], and that Ca(2+)/calmodulin (CaM) regulated the F-actin-bundling activity of EF-1 alpha [Kurasawa et al. (1996) J. Biochem. 119, 791-798]. In the present study, we investigated the binding between Tetrahymena EF-1 alpha and CaM using a Tetrahymena EF-1 alpha affinity column, and the localization of EF-1 alpha and CaM by indirect immunofluorescence. Only CaM in the Tetrahymena cell extract bound to Tetrahymena EF-1 alpha in a Ca(2+)-dependent manner. In interphase Tetrahymena cells, EF-1 alpha and CaM are colocalized in the crescent structure of the oral apparatus and the apical ring, while in dividing cells, they are colocalized in the division furrow. This is the first report describing the coexistence of EF-1 alpha and CaM in the division furrow, suggesting that EF-1 alpha and CaM are involved in the organization of contractile ring microfilaments during cytokinesis.

MACRONUCLEAR DIVISION AND CYTOKINESIS IN TETRAHYMENA

Tetrahymena contains a micronucleus and a macronucleus. The micronucleus divides with typical mitosis, while the macronucleus divides amitotically. Although the mechanism responsible for macronuclear division was previously unknown, we clarified the organization of microtubules during macronuclear division. The macronuclear microtubules dynamically changed their distribution in an organized way throughout the macronuclear division. The macronuclear microtubules and the cytoplasmic microtubules cooperatively carried out the macronuclear division. When the micronuclear division was finished, p85 appeared at the presumptive division plane prior to the cytokinesis. The p85 directly interacted with calmodulin in a Ca2+-dependent manner, and p85 and CaM colocalized to the division furrow during cytokinesis. Moreover, the Ca2+/CaM inhibitor, W7, inhibited the direct interaction between p85 and CaM, the localization of both proteins to the division plane, and the formation of the division furrow. Thus, Ca2+/CaM and p85 have important roles in initiation and progression of cytokinesis in Tetrahymena.

Ca(2+)/calmodulin and p85 cooperatively regulate an initiation of cytokinesis in Tetrahymena.

Tetrahymena p85 differs in mobility in two-dimensional SDS-polyacrylamide gel electrophoresis between wild-type and temperature-sensitive cell-division-arrest mutant cdaA1 cell extracts, and is localized to the presumptive division plane before the formation of the division furrow. The p85 contained three identical sequences which show homology to the calmodulin binding site of Ca(2+)/calmodulin dependent protein kinase Type II in Saccharomyces cerevisiae. We found the p85 directly interacts with Tetrahymena calmodulin in a Ca(2+)-dependent manner, using a co-sedimentation assay. We next examined the localization of p85 and calmodulin during cytokinesis using indirect immunofluorescence. The results showed that both proteins colocalize in the division furrow. This is the first observation that calmodulin is localized in the division furrow. Moreover, the direct interaction between p85 and Ca(2+)/calmodulin was inhibited by Ca(2+)/calmodulin inhibitor N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide HCl. When the cells were treated with the drug just before the beginning of cytokinesis, the drug also inhibited the localization of p85 and calmodulin to the division plane, and the formation of the contractile ring and division furrow. Therefore, we propose that the Ca(2+)/calmodulin signal and its target protein p85 cooperatively regulate an initiation of cytokinesis and may be also concerned with the progression of cytokinesis in Tetrahymena.

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.

Distribution of a centrosomal antigen during morphogenesis in the ciliated protozoan Euplotes

Ciliates assemble basal bodies in great number at many stages of the life-cycle. In order to understand their assembly mechanisms, we screened a library of monoclonal antibodies directed against pericentriolar material. One of these antibodies, CTR210, was used previously to follow steps of this assembly process: in Paraurostyla, new basal bodies appear along a scaffold of linear structures recognized by this antibody. The very unusual behavior of this antigen deserved confirmation in other species. In the present study, we show by immunofluorescence that, in another phylogenetically very distant species, Euplotes, basal bodies are assembled in the same pathway during division. In addition, this antibody recognizes a filamentous ring located at the division furrow and linking many basal body assemblages. By cell fractionation and cytoskeletal extraction, we obtained fractions enriched in basal bodies and associated material. Such fractions still display a high complexity in protein composition. These fractions were used to characterize the main target of the antibody as a doublet of 45 kDa. These results confirm previous results in terms of functionality of the protein recognized by the antibody, but raise new questions in terms of the assignment of the recognized protein to the HSP70 family as hypothesized previously.

Distribution of a centrosomal antigen during morphogenesis in the ciliated protozoan Euplotes

Ciliates assemble basal bodies in great number at many stages of the life-cycle. In order to understand their assembly mechanisms, we screened a library of monoclonal antibodies directed against pericentriolar material. One of these antibodies, CTR210, was used previously to follow steps of this assembly process: in Paraurostyla, new basal bodies appear along a scaffold of linear structures recognized by this antibody. The very unusual behavior of this antigen deserved confirmation in other species. In the present study, we show by immunofluorescence that, in another phylogenetically very distant species, Euplotes, basal bodies are assembled in the same pathway during division. In addition, this antibody recognizes a filamentous ring located at the division furrow and linking many basal body assemblages. By cell fractionation and cytoskeletal extraction, we obtained fractions enriched in basal bodies and associated material. Such fractions still display a high complexity in protein composition. These fractions were used to characterize the main target of the antibody as a doublet of 45 kDa. These results confirm previous results in terms of functionality of the protein recognized by the antibody, but raise new questions in terms of the assignment of the recognized protein to the HSP70 family as hypothesized previously.

Division planes alternate in spherical cells of Escherichia coli.

In the spherical cells of Escherichia coli rodA mutants, division is initiated at a single point, from which a furrow extends progressively around the cell. Using "giant" rodA ftsA cells, we confirmed that each new division furrow is initiated at the midpoint of the previous division plane and runs perpendicular to it.

A new Tetrahymena actin-binding protein is localized in the division furrow.

Using an F-actin affinity column, a 60 kDa fragment of a 71 kDa F-actin-binding protein was partially purified from Tetrahymena pyriformis. After digestion of the 60 kDa fragment with cyanogen bromide, the N-terminal 21-amino acid sequence of one of the resulting peptides was found to show sequence similarity to a region near the actin-binding site (amino acid residues 260-281) of yeast fimbrin. An antibody prepared against a synthesized 21-mer oligopeptide reacted with the 71 kDa proteins in T. pyriformis and T. thermophila cell extracts, suggesting that the 60 kDa fragment was produced from the 71 kDa protein through partial digestion occurring during isolation. The 60 kDa fragment bound to Tetrahymena F-actin as well as to rabbit skeletal muscle F-actin, and induced the bundling of Tetrahymena F-actin. Indirect immunofluorescence revealed colocalization of the 71 kDa protein and actin in the oral apparatus and the deep fiber bundles in T. pyriformis. On the other hand, in T. thermophila, the 71 kDa protein was localized in the oral apparatus and the contractile vacuole pores during the interphase. During cytokinesis, the 71 kDa protein was localized in the division furrow. Therefore, the 71 kDa protein seems to associate with the actin cytoskeleton, and to regulate the actin filament organization during phagocytosis and cytokinesis in Tetrahymena.

Map kinase activation and RAF-1 synthesis in blue fox oocytes is controlled by cumulus granulosa cells

Eggs of Paracentrotus lividus were pretreated with doses of trypsin that brought about a dissolution of the vitelline membrane, whereas the cytoplasm often exhibited a certain excess gelation as described in a previous paper [27]. In these eggs an expulsion of the cortical granules takes place; these are converted into rods and plates. Above the region of sperm entry the particles are closely aggregated, whereas they are dispersed in a more distal region and absent in the region opposite to that of sperm entry.In eggs approaching cytoplasmic cleavage the rods and plates move in the direction of the cleavage plane, where they accumulate and aggregate. The rods and plates move in a layer that is outside the egg surface but follow the movements of this latter. The particles carry out a certain Brownian movement which is damped when the furrow formation begins. After completion of the furrow the Brownian movement increases again and the particles are dispersed over the egg surface. In preparation for the second cleavage the accumulation of the rods and plates toward the cleavage plane is repeated. The degree of aggregation of the particles is variable. In many cases the aggregated particles bridge over the cleavage furrow like a continuous membrane, whereas the poles are devoid of particles. In many eggs of this kind bulges are formed at the division poles.The movements of cortical granules toward the cleavage furrow are also observed in eggs where the formation of a fertilization membrane occurs. Under certain circumstances a number of cortical granules do not join the membrane and are not converted into rods and plates. Accumulation of the granules toward the division plane and changes in their Brownian movement are also observed here.Partial fertilization of eggs was caused by temporary warming of the eggs soon after insemination [3, 26]. In these eggs the membrane covers only a certain region of the egg. If a division furrow appears in the neighbourhood of the border of the fertilization membrane, this latter expands so as to cover also the adjacent part of the furrow.The elevation of the fertilization membrane may be prevented by pipetting the eggs 30 seconds after insemination into the slit between coverslip and slide. These eggs divided and it is described how the fertilization membrane may bulge and become more refractive above the cleavage furrow.The phenomena described may be the due to the action of a gelating factor that plays a role both infertilization and cytoplasmic cleavage. The gleating factor may also be of importance for the cortical movements occurring in connection with cleavage [4–10]. Similar movements are noted to occur also toward the region of sperm attachment. The nature of the gelating factor is discussed on the basis of data showing that certain doses of trypsin are able to activate a gelating factor in the egg [27]. This factor has probably the nature of an enzyme.Certain additional observations are reported in order to demonstrate that considerable movements of the cortical layer may be induced in oocytes.

The mutant gene product of a Tetrahymena cell-division-arrest mutant cdaA is localized in the accessory structure of specialized basal body close to the division furrow.

A division arrest mutant, cdaA, of Tetrahymena thermophila is known to have a temperature sensitive-defect in the determination of the division plane, and its gene product had been shown to be a protein designated as p85 (Mr = 85,000; pI = 4.7). Here the localization of p85 was shown to be the accessary structure of specialized basal body close to the division furrow by immunoelectron microscopy using anti-p85 antiserum.

Dithiothreitol prevents membrane fusion but not centrosome or microtubule organization during the first cell cycles in sea urchins.

Dithiothreitol (DTT), a disulfide reducing agent, inhibits the fusion of male and female pronuclei within the activated cytoplasm of sea urchin eggs. The migrations of the pronuclei are not affected by DTT, indicating that microtubule function is not impaired. Centrosomal antigens are detected in the sperm aster and in all subsequent microtubule-based configurations. Nuclear membranes never fuse and the chromatin of male and female pronuclei never mix in the DTT-treated cells. During prophase, when nuclear envelopes break down to undergo mitosis, both sets of chromosomes undergo condensation cycles independent from each other. Both pronuclei initially stain for centrosomal material and surrounding microtubules. With time, the female's centrosomal material as well as the microtubules disappear while the male forms a bipolar spindle. Interestingly, one pole of the paternal mitotic apparatus communicates with the separate maternal chromatin, forming a half spindle which moves the egg-derived chromatin towards its pole. At the time for cell division, the individual karyomeres are not able to fuse their nuclear membranes to reconstitute the blastomere nuclei. When DTT is applied at prometaphase of the first cell cycle, the chromosome cycle continues until next metaphase. Centrosomes also continue their cycle and undergo somewhat atypical splitting during the time for second telophase. Division furrows are initiated but aborted. These results support the hypothesis that disulfide groups are required for membrane fusion of the pronuclei, for membrane fusion of the karyomeres, and for the completion of the division furrow to achieve successful cell division.

Tetrahymena profilin is localized in the division furrow.

Localization of Tetrahymena profilin was examined by an immunofluorescence method. In interphase Tetrahymena cells, immunofluorescence for profilin was diffusely distributed in the cytoplasm, while in dividing cells, additional intense fluorescence was observed in the division furrow. From the result of immunofluorescence localization using cytoskeletal cell models, a significant fraction of profilin appeared to become insoluble in association with a cytoskeletal structure just beneath the division furrow during cytokinesis, although remaining profilin existed as a soluble form in the cytoplasm. Double immunofluorescence staining with anti-profilin and anti-actin antibodies revealed that the localization of profilin in the division furrow coincided with that of contractile ring microfilaments in terms of both position and timing. This is the first report describing the coexistence of profilin with actin filaments in the division furrow, implying the possible involvement of profilin in assembly and disassembly of contractile ring microfilaments in the process of cytokinesis.

The Nuclear Apparatus of the Ditransversal Ciliate Homalozoon vermiculare (Ciliophora, Rhabdophora) during Interphase and Division. I. The Macronucleus1

ABSTRACT. The nuclear apparatus of Homalozoon vermiculare consists of a single moniliform macronucleus and about 25 micronuclei. The number of macronuclear segments depends (i) on the number of divisions of individual segments during the interphase and (ii) on the number of segments that arise prior to cytokinesis from the (temporary) filiform macronucleus. Precytokinetic changes of the macronucleus involve the fusion of individual segments followed by contraction and subsequent elongation of the entire macronucleus. The chromatin bodies uncoil into fine fibrils during macronuclear contraction. At the time when the division furrow appears, the macronucleus starts to renodulate. The interphase segment contains a more or less reticulated chromatin body partly attached to the nuclear envelope and about 30 polymorphous nucleoli. The latter consist of the pars granulosa, the pars fibrosa, and an additional fibrillar component. The nucleoli undergo drastic changes prior to division and the granular component disappears completely during macronuclear condensation. On the average, the macronucleus contains a 3,400‐fold amount of DNA compared with a haploid micronucleus, but the intraspecific differences in the DNA content of the entire macronucleus are extremely large. In contrast, DNA content and size of an individual segment of the macronucleus are precisely regulated during interphase.

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.

Tetrahymena actin: localization and possible biological roles of actin in Tetrahymena cells.

Though actin is ubiquitous in eukaryotes, its existence has not been clearly proven in Tetrahymena. Recently, we have succeeded in cloning and sequencing the Tetrahymena actin gene using a Dictyostelium actin probe (Hirono, M. et al. (1987) J. Mol. Biol. 194, 181-192). The primary structure of the Tetrahymena actin deduced from the nucleotide sequence of its gene is greatly divergent from those of other known actins, making it necessary to ascertain whether the predicted Tetrahymena actin is indeed an actin. In this paper, we investigated the localization of the predicted Tetrahymena actin by an immunofluorescence technique using antibody against its synthetic N-terminal peptide, in order to elucidate its possible biological roles. The results showed that immunofluorescence was localized in the division furrow of the dividing cell, and in the intranuclear filament bundles formed in cells exposed to heat shock or DMSO. In addition, the oral apparatus and the proximity of the cytoproct, which are organelles involved in endocytosis and exocytosis, respectively, also fluoresced. Thus, we conclude that the Tetrahymena actin we identified is indeed an actin and plays the same biological roles as ubiquitous actins do, although it is considerably divergent in its amino acid sequence.

Growth-correlated distribution of two types of plasma membrane particles of Schizosaccharomyces pombe

The particle ultrastructure at or near the growing pole and in lateral regions of the plasma membrane of exponential phase Schizosaccharomyces pombe was examined by means of the freeze-fracture technique. The uninvaginated growing pole was predominantly embedded with small globular particles of 4–8 nm in diameter with no depressions. In contrast, densely invaginated lateral regions, where no growth occurs, were rich in large cratered particles of 10–15 nm in diameter with central depressions. On cytokinesis, the middle of the cell near the division furrow became uninvaginated and was predominantly embedded with small globular particles. This is the first report directly concerning the growth-correlated distribution of yeast plasma membrane particles.

Purification and immunofluorescence localization of the mutant gene product of a Tetrahymena cdaA1 mutant affecting cell division.

A division arrest mutant, cdaA, of Tetrahymena thermophila is known to have a ts-defect in the formation of the fission zone which determines the position of the fission plane. A protein (Mr = 85,000; pI = 4.7, designated as p85) has recently been identified in our laboratory as a possible gene product of the cdaA locus by two-dimensional gel electrophoresis and genetic experiments (Ohba et al., submitted). In the present research, we have isolated p85, prepared its antibody, and demonstrated that in wild-type cells or in cdaA cells at permissive temperature, immunofluorescence for p85 appears on the equatorial basal bodies at the predicted fission zone just before formation of the zone. In such a case, the fission zone appears to be formed just anterior to the fluorescence-associated basal bodies, and then constriction of the division furrow occurs at the zone. However, in cdaA cells at the restrictive temperature, the equatorial p85 deposit and subsequent fission zone formation and furrowing do not occur at all. Thus, we conclude that p85 plays a key role in the formation of the fission zone and in the positioning of the equatorial fission line.

Induced Formation of Abnormal Cells in Axenic Culture of Paramecium aurelia: I. Cell Surface and Nuclear Apparatus Visualization Using Double Sequential Fluorescent Labelling

The chains of Paramecium cells and different kinds of the monsters have been obtained in axenic media of diverse composition. In cultures fed in excess (in double concentrated standard axenic medium) such forms appeared 3–4 days after inoculation. Fluorescent labelling of living cell surface with CDC and afterwards of nuclear apparatus with DAPI has been applied for characterization of the obtained forms. CDC labelling demonstrated the continuity of the surface membrane along the whole monsters and revealed a division furrow which had not been completed in the majority of chains formed. Dislocation of macro- and micronuclei as well as intercalary division has been detected in examined abnormal forms. The observed monstrosity has not been inherited: transferring to normal medium gave the normal specimens which in turn formed monsters in overfed conditions. The described abnormal forms of P. aurelia seem to be an interesting model in cell biology research and the technique of double sequential fluorescent labelling has been found especially useful in these studies.