Dynamic changes in microtubule organization during division of the primitive dinoflagellate Oxyrrhis marina

The marine dinoflagellate Oxyrrhis marina has three major microtubular systems: the flagellar apparatus made of one transverse and one longitudinal flagella and their appendages, cortical microtubules, and intranuclear microtubules. We investigated the dynamic changes of these microtubular systems during cell division by transmission and scanning electron microscopy, and confocal fluorescent laser microscopy. During prophase, basal bodies, both flagella and their appendages were duplicated. In the round nucleus situated in the cell centre, intranuclear microtubules appeared radiating toward the centre of the nucleus from densities located in some nuclear pores. During metaphase, both daughter flagellar apparatus separated and moved apart along the main cell axis. Microtubules of ventral cortex were also duplicated and moved with the flagellar apparatus. The nucleus flattened in the longitudinal direction and became discoid-shaped close to the equatorial plane. Many bundles of microtubules ran parallel to the short axis of the nucleus (cell long axis), between which chromosomes were arranged in the same direction. During ana-telophase, the nucleus elongated along the longitudinal axis and took a dumbbell shape. At this stage a contractile ring containing actin was clearly observed in the equatorial cortex. The cortical microtubule network seemed to be cut into two halves at the position of the actin bundle. Shortly after, the nucleus divided into two nuclei, then the cell body was constricted at its equator and divided into one anterior and one posterior halves which were soon rebuilt to produce two cells with two full sets of cortical microtubules. From our observations, several mechanisms for the duplication of the microtubule networks during mitosis in O. marina are discussed.     

Egg maturation and parthenogenetic recovery of diploidy in the scorpion Liocheles australasiae (Fabricius) (Scorpions, ischnuridae)

In the scorpion Liocheles australasiae, egg maturation and parthenogenetic recoveries of chromosome number and nuclear DNA content were examined by histological, karyological observations and quantitative measurements of DNA. The primary oocyte becomes mature through two successive maturation divisions. The first maturation division takes place in the primary oocyte to produce a secondary oocyte and a first polar body. The second maturation division soon occurs in the secondary oocyte, in which the nucleus is divided into a mature egg nucleus and a second polar body nucleus, not followed by cytoplasmic fission. The first polar body, in one case, was successively divided into two second polar bodies; in the other case it was not divided. In either case, these polar bodies remained attached to the early embryo. The fate of these polar bodies during further embryogenesis were studied. In the karyological analysis, the chromosome number was divided into two groups, one from 27-32, the other was 54-64. The former was presumably the metaphase chromosome number at the meiotic division; the latter was presumably the metaphase chromosome number at the mitotic division. DNA content in the diploid nucleus of the primary oocyte, doubled before the maturation divisions, was reduced through the maturation divisions by one-half in the nuclei of the secondary oocyte and the first polar body and by one-fourth in the nuclei of the egg and the second polar bodies. The first reduction of DNA content corresponded to halving the number of the chromosomes in the first maturation division and the second to the nuclear division in the secondary oocyte. These reductions represent a common process of egg maturation, except the final production of the mature egg with two haploid nuclei, an egg nucleus, and a second polar body nucleus. These two nuclei, which were formed apart in the mature egg, drew near to fuse into a zygote nucleus. The chromosome number and nuclear DNA content were doubled in the zygote and each blastomere in embryos, supporting the hypothesis that the egg nucleus fuses with the second polar body nucleus and this conjugation initiates subsequent embryonic development.     

Quantitative evaluation of cell orientation in culture.

A quantitative method to assess mutual orientation of cells in cultures on a substrate includes the following operations: (1) the cellular groups to be evaluated are chosen; (2) position of the long axis for each nucleus of the group is determined; (3) the axis OX is arbitrary chosen for every group and the angles alphai between the long axis of every nucleus i and the axis OX are measured. Every nucleus i corresponds to a vector of unit length ei with the angles 2alpha. D, the mean of the vectors ei for every cell group is calculated. This value of D is compared with a set of values of D computed according to a model of mutual orientation studies in a simulation experiment. In this model the group of n vectors consists of a fraction of Kn parallel vectors (o less than or equal to K less than or equal to I) and of (I minus K)n randomly oriented vectors. K corresponding to the computed D which is equal to the experimental value of D is considered as an index of orientation for the group. Contact orientation with respect to the relief of the substrate may be evaluated as a root mean square deviation sigma0 to the angles between the long axes of cell nuclei and the direction of relief. Examples of the measurements of K and sigma0 in cell cultures are given.     

Endogenous Bud Formation in Histriculus vorax, a New Asexual Reproductive Process In the Hypotrichida

SYNOPSIS. Histriculus vorax (Stokes) Corliss, a hypotrichous ciliate, has been separated from activated sludge and cultured monoxenically in the laboratory. The asexual life cycle has been observed and the stages of development photographed. There are large variations in shape and size of cells within clonal cultures. Both large (190–250 μ long) and small (70–140 μ long) cells are capable of normal asexual binary fission but only the large cells are able to grow endogenous buds, which, when mature, are extruded through the body wall of the mother cell. Newly deposited buds can either develop directly into an embryonic form, or, if unfavorable conditions prevail, first encyst. Similar embryonic stages bearing caudal and frontal cirri are produced both by direct development and by excystment of the encysted bud. Embryos develop rapidly into trophic forms which finally grow into small adults capable of asexual binary fission. During binary fission the nuclei behave as described previously for other members of the Oxytrichidae. A reorganization band forms at the outer end of each macronucleus, and these bands move along the macronuclei towards each other, finally disappearing at the inner ends. A fusion nucleus is then formed which splits into 4 pieces, 2 of which pass to the proter and 2 to the opisthe. During bud formation the reorganisation bands form and move as in binary fission. No fusion nucleus is formed, but the macronuclei divide immediately after reorganization, and the anterior macronucleus of each pair so produced migrates to the budding region. The infraciliature of H. vorax resembles that of Opisthotricha monspessulana. 'Erratic' kinetosomes, which are present in the adult, divide during binary fission and so produce the infraciliature of the proter and opisthe. During bud formation the budding region receives a number of these 'erratic' kinetosomes from the mother cell, and these divide to form the infraciliature of the bud.     

Is actin involved in the nuclear division in Amoeba proteus?

During semi-open mitosis of Amoeba proteus the nuclear envelope is not dispersed and nucleus divides by fission. The presence of actin layer close to nuclear envelope was demonstrated in interphase and telophase nuclei of that amoeba stained with rhodamine labelled phalloidin. In telophase, an accumulation of actin arises in the space between the future daughter nuclei. It appears to be comparable with the contractile ring of dividing cells. This suggests that actin associated with the nuclear envelope of Amoeba proteus may be involved in final separation of the daughter nuclei, forming a constriction ring at the middle of dividing nucleus.     

Mitosis in the Hemoflagellate Trypanosoma cyclops*

SYNOPSIS. The ultrastructure of interphase and mitotic nuclei of the epimastigote form of Trypanosoma cyclops Weinman is described. In the interphase nucleus the nucleolus is located centrally while at the periphery of the nucleus condensed chromatin is in contact with the nuclear envelope. The nucleolus fragments at the onset of mitosis, but granular material of presumptive nucleolar origin is often recognizable in the mitotic nucleus. Peripheral chromatin is in contact with the nuclear envelope throughout mitosis, and it seems reasonable to assume that the nuclear envelope is involved in its segregation to the daughter nuclei. Spindle microtubules extend between the poles of the dividing nucleus and terminate close to the nuclear envelope. The basal body and kinetoplast divide before the onset of mitosis and do not appear to have any morphologic involvement in that process. Spindle pole bodies, kinetochores, and chromosomal microtubules have not been observed.     

Pyrotheca hydropsycheae N. Sp., a Microsporidian Parasite of Caddis Fly Larvae,Hydropsyche siltalai Döhler, 1963 (Trichoptera,Hydropsychidae)1

ABSTRACT. Pyrotheca hydropsycheae n. sp. is described from caddis fly larvae, Hydropsyche siltalai Döhler, 1963. All stages were found in oenocytes and fat body cells. Meronts were uni- or binucleate with simple surface membranes. The sporogonic stages were recognized ultrastructurally by the separation of an envelope, the sporophorous vesicle, from their surfaces. Mature sporogonial plasmodia were tetranucleate and gave rise by longitudinal fission to four uninucleate elongate sporoblasts with polar nuclei. Spores were lageniform with an inflated posterior end, containing the polar tube coils and the nucleus, and a narrow anterior section comprising two-thirds of the length, containing the polaroplast and straight part of the polar tube. The polaroplast consisted of an anterior region of loosely packed membranes arranged as partitions at angles to one another and a posterior region of increasingly closely packed parallel membranes. The spore wall consisted of an electron-dense exospore with a fuzzy coat and a thin electron-lucent endospore. All four spores derived from a sporont faced in the same direction in the sporophorous vesicle. Spores measured 8.7 μm long and extruded polar filaments were about 20 μm.     

Nuclear and manchette development in spermatids of normal and azh/azh mutant mice

Germinal cells or nuclei with attached cytoskeletal elements were prepared from the testes and epididymides of normal mice and mice homozygous for the recessive azh mutation, which results in abnormal sperm heads. To make observations, we utilized phase-contrast microscopy, immunofluorescence microscopy with antitubulin antibodies, and a direct-view stereo electron microscope system developed by A. Cole. Sperm nuclei, tails, manchettes, and other cytoskeletal structures were studied at various stages of development. The tail architectures were similar in the normal and mutant forms, but the shape of the heads at the attachment regions were markedly different. Normal sperm nuclei were very flat, whereas the posterior regions of mutant nuclei were tapered cylinders. The manchette, an organized microtubular structure that girdles the posterior region of the spermatid nucleus, differed in size and configuration between normal and mutant forms. In normal midstage spermatids, the manchette microtubules extended outward at a 45 degree angle from the long axis of the flattened head, whereas in mutant spermatids, the microtubules formed tapered cylinders around the long axis of the caudal part of the nucleus. Radical differences in head shapes between normal and mutant sperm could be related, in part, to the manner in which manchettes formed and matured on the spermatids.     

Interdependence of cell cycle events inSchizosaccharomyces pombe. Terminal phenotypes of cell division cycle mutants arrested during dna synthesis and nuclear division

Summary Temperature-sensitive cell division cycle (cdc) mutants of the fission yeastSchizosaccharomyces pombe, previously characterized as defective in nuclear division were examined by thin section electron microscopy. All of the mutants failed to enter mitosis, rather they accumulated at one of four distinct terminal phenotypes. Class one were arrested with a nucleus rectangular in cross-section and a laterally situated spindle pole body (SPB). The second group had spherical or rectangular nuclei with a single SPB. The sole member of the third group wascdc 27. K 3, which had a spherical crenated nucleus with a single SPB from which microtubules emerged and extended into the cytoplasm. Allelic variants ofcdc 25 comprised the fourth group all of which displayed aberrant nuclear morphologies. Utilizing this ultrastructural data together with a knowledge of the transition points of these mutants a model for the interdependence of certain cell cycle event is proposed in which the initiation of DNA synthesis is uncoupled from the replication and separation of the SPB. This paper also provides new information on SPB structure inS. pombe. This is discussed in connection with the transient assembly of both spindle and cytoplasmic microtubules.     

Asexual reproduction of planarians: Metric studies

A relationship was studied between fission and restoration of body and its individual parts under different experimental conditions in planarians of the Dugesia tigrina asexual race. The body and its fragments were studied morphomterically. After fission, the growth of planarians demonstrated topographic differences. The separated tail fragments and postpharyngeal area, in which the zone of fission is formed, were growing at the highest rate. More active growth was also noted over the long body axis. Fission and growth were more active in isolated planarians, as compared to those kept in groups.     

Trypanosoma brucei Polo-like kinase is essential for basal body duplication, kDNA segregation and cytokinesis

Polo-like kinases (PLKs) are conserved eukaryotic cell cycle regulators, which play multiple roles, particularly during mitosis. The function of Trypanosoma brucei PLK was investigated in procyclic and bloodstream-form parasites. In procyclic trypanosomes, RNA interference (RNAi) of PLK, or overexpression of TY1-epitope-tagged PLK (PLKty), but not overexpression of a kinase-dead variant, resulted in the accumulation of cells that had divided their nucleus but not their kinetoplast (2N1K cells). Analysis of basal bodies and flagella in these cells suggested the defect in kinetoplast division arose because of an inhibition of basal body duplication, which occurred when PLK expression levels were altered. Additionally, a defect in kDNA replication was observed in the 2N1K cells. However, the 2N1K cells obtained by each approach were not equivalent. Following PLK depletion, the single kinetoplast was predominantly located between the two divided nuclei, while in cells overexpressing PLKty, the kinetoplast was mainly found at the posterior end of the cell, suggesting a role for PLK kinase activity in basal body and kinetoplast migration. PLK RNAi in bloodstream trypanosomes also delayed kinetoplast division, and was further observed to inhibit furrow ingression during cytokinesis. Notably, no additional roles were detected for trypanosome PLK in mitosis, setting this protein kinase apart from its counterparts in other eukaryotes.     

Origin and Morphogenetic Movements of the Pores of the Contractile Vacuoles in Paramecium qurelia

The position of the contractile vacuoles in non-dividing Paramecium aurelia, as judged by that of the pores, is relatively constant both laterally and longitudinally, as is the distance between them. Some variability of the distance between the pores persists from the recent fission among the smaller animals of normal shape. At the onset of fission two new vacuoles appear, one anterior to each of the old vacuoles; all the vacuoles must undergo relocation because their mean positions now are somewhat removed from that in the non-dividing animals. The pores of the front daughter are too close together: the anterior pore is too far back, and the posterior is too far forward; likewise the pores of the hind daughter are too close together: the anterior too far forward as well as the posterior. The relocation does not begin until shortly before separation of the daughters and is practically complete by the time the daughters have assumed their normal length/width ratio after separation. A neuroneme connects the pore to one of the basal granules adjacent to its place of origin, now far removed.
Occasionally more than one new pore appears at the usual time and place during very early fission; these are very close together and usually serve a single vacuole. However, most of them fail to survive the relocation following this and the next fission, so they are found in the posterior position very rarely. But, in some individuals they may survive and serve a single or separate vacuoles. In a certain clone of Paramecium aurelia multiple pores and vacuoles are rather frequent; these are, of course, the result of the tendency to produce multiple pores and vacuoles at the time of fission.     

Reproduction by Binary and Multiple Fission in Gigantomonas*

SYNOPSIS. Gigantomonas usually exists in the multinucleate stage. Hence, multiple fission is more common than binary fission. In its flagellate as well as its aflagellate state it is always an amoeboid cell which possesses from one to several large, clear pseudopodia. Fairly often in the multinucleate, as well as the uninucleate, stage no extranuclear organelles are present except large plain centrioles, two of which are always closely associated with each nucleus. During nuclear reproduction four centrioles, two old ones and two new ones, are always present with each nucleus. During all nuclear reproductions, regardless of the number of nuclei present, extranuclear organelles, such as flagella, axostyle, undulating membrane, and costa when present are discarded. If they are renewed, it is by the new centrioles at the same time that the old ones produce new central spindles, two always cooperating in the process. Thus, Gigantomonas, like other genera of the Devescovinidae, the family to which it belongs, never has for each nucleus present more than one set of extranuclear organelles, a characteristic which Devescovinidae and Lophomonadidae have in common. It is the only genus of Devescovinidae without a parabasal body. Owing to the liquidness of the cytoplasm, the central spindle, which becomes very long indeed, often extends beyond the cytoplasm and thus pushes the nucleus fastened to this end of it completely out of the cell. Mainly because of this situation, multinucleate forms with an odd number of nuclei occur often; otherwise the nuclear numbers would be 2, 4, 8, 16, 32, etc., because, no matter how many nuclei are present, they all reproduce simultaneously or nearly so. An unusual situation occurs in which Gigantomonas ingests and digests a small species of Holomastigotoides, while several hundred individuals of the latter become attached to and destroy Gigantomonas.     

ULTRASTRUCTURAL FEATURES OF MITOSIS IN PLOEOTIA COSTATA (HETERONEMATALES,EUGLENOPHYTA)1

The ultrastructural features of mitosis in the colorless phagotrophic euglenoid, Ploeotia costata (Farmer and Triemer 1988bn; syn: Serpenomonas costata, Triemer 1986) are described. During interphase the nucleus is rounded and lies adjacent to the reservoir and the four basal bodies, two of which bear flagella. At the onset of mitosis, two additional flagella are generated from the accessory basal bodies such that four basal bodies with flagella now lie at one pole of the prophase nucleus. Microtubules develop in the nucleus prior to migration of one of the basal body pairs to the opposite pole of the nucleus. By metaphase, chromosomes with layered kinetochores are aligned on the equator of the spindle, and a dumbbellshaped nucleolus stretches from pole to pole. Continued elongation of the nucleus results in the separation of the chromosomal masses at anaphase. The distance between the nuclear poles from metaphase to anaphase changes little although the overall length of the nucleus nearly doubles. By telophase a large interzonal spindle develops between the forming daughter nuclei. The extended interzonal spindle breaks near the center prior to cell cleavage.     

Asexual reproduction of planarians: metric studies

A relationship was studied between fission and restoration of body and its individual parts under different experimental conditions in planarians of the Dugesia tigrina asexual race. The body and its fragments were studied morphomterically. After fission, the growth of planarians demonstrated topographic differences. The separated tail fragments and postpharyngeal area, in which the zone of fission is formed, were growing at the highest rate. More active growth was also noted over the long body axis. Fission and growth were more active in isolated planarians, as compared to those kept in groups.     

Control of development of the oral apparatus of Paramecium during sexual reproduction: an embryological perspective

This study shows that development of the new soma during sexual reproduction in ciliates can be conceptualized on the same basis as embryogenesis in multicellular organisms. In conjugating Paramecium, development of a new oral apparatus takes place during fertilization and the first three divisions of the zygotic nucleus and completes well before the postsexual cell undergoes the first cell fission. The control of oral development is analyzed by microsurgical removal of the zygotic nucleus or the postzygotic nuclei from conjugants. The enucleated exconjugants can pass through an early hurdle in oral development (the initiation of oral membranelle assembly) and subsequently develop an oral apparatus. Such oral apparatuses nevertheless exhibit structural and functional abnormalities including fragmentation and misalignment of oral membranelles, absence of the postoral microtubular bundle, reduction in the length of buccal cavity, and impaired phagocytosis. Other stomatogenic aspects, such as the arrangement of basal bodies in the oral membranelles, remain unaffected. The two groups of exconjugants, one derived from cells enucleated at the zygotic stage, and the other at the postzygotic stage, exhibit the same types of oral abnormality. We conclude that (i) the zygotic nucleus is not essential for the initiation of oral membranelle assembly. The existence of zygotic signals for subsequent oral development is not ruled out, but these are insufficient. (ii) Postzygotic nuclei, as well as maternal nuclei (the old somatic nucleus and meiotic derivatives of the germ nucleus), control oral development. This reveals a parallelism between postsexual development in ciliates and the early embryology of multicellular organisms, in their reliance on information provided by maternal, as well as early postzygotic nuclei. (iii) The activity of the old somatic nucleus alone is not sufficient for the later stages of oral development. Probably, some stomatogenic functions of the old somatic nucleus normally utilized for the later stages of oral development in binary fission are inactivated during sexual reproduction. Alternatively, the old somatic nucleus may rely on some critical conditions prescribed by the postzygotic nuclei in order to act.     

A novel fission yeast gene, kms1 +, is required for the formation of meiotic prophase-specific nuclear architecture

In the meiotic prophase nucleus of the fission yeast Schizosaccharomyces pombe, chromosomes are arranged in an oriented manner: telomeres cluster in close proximity to the spindle pole body (SPB), while centromeres form another cluster at some distance from the SPB. We have isolated a mutant, kms1, in which the structure of the meiotic prophase nucleus appears to be distorted. Using specific probes to localize the SPB and telomeres, multiple signals were observed in the mutant nuclei, in contrast to the case in wild-type. Genetic analysis showed that in the mutant, meiotic recombination frequency was reduced to about one-quarter of the wild-type level and meiotic segregation was impaired. This phenotype strongly suggests that the telomere-led rearrangement of chromosomal distribution that normally occurs in the fission yeast meiotic nucleus is an important prerequisite for the efficient pairing of homologous chromosomes. The kms1 mutant was also impaired in karyogamy, suggesting that the kms1 ⁺ gene is involved in SPB function. However, the kms1 ⁺ gene is dispensable for mitotic growth. The predicted amino acid sequence of the gene product shows no significant similarity to known proteins.     

Vesicle-like biomechanics governs important aspects of nuclear geometry in fission yeast

It has long been known that during the closed mitosis of many unicellular eukaryotes, including the fission yeast (Schizosaccharomyces pombe), the nuclear envelope remains intact while the nucleus undergoes a remarkable sequence of shape transformations driven by elongation of an intranuclear mitotic spindle whose ends are capped by spindle pole bodies embedded in the nuclear envelope. However, the mechanical basis of these normal cell cycle transformations, and abnormal nuclear shapes caused by intranuclear elongation of microtubules lacking spindle pole bodies, remain unknown. Although there are models describing the shapes of lipid vesicles deformed by elongation of microtubule bundles, there are no models describing normal or abnormal shape changes in the nucleus. We describe here a novel biophysical model of interphase nuclear geometry in fission yeast that accounts for critical aspects of the mechanics of the fission yeast nucleus, including the biophysical properties of lipid bilayers, forces exerted on the nuclear envelope by elongating microtubules, and access to a lipid reservoir, essential for the large increase in nuclear surface area during the cell cycle. We present experimental confirmation of the novel and non-trivial geometries predicted by our model, which has no free parameters. We also use the model to provide insight into the mechanical basis of previously described defects in nuclear division, including abnormal nuclear shapes and loss of nuclear envelope integrity. The model predicts that (i) despite differences in structure and composition, fission yeast nuclei and vesicles with fluid lipid bilayers have common mechanical properties; (ii) the S. pombe nucleus is not lined with any structure with shear resistance, comparable to the nuclear lamina of higher eukaryotes. We validate the model and its predictions by analyzing wild type cells in which ned1 gene overexpression causes elongation of an intranuclear microtubule bundle that deforms the nucleus of interphase cells.     

Vegetative nuclear structures and their mode of division inCyathus species

Vegetative nuclear division in the homokaryotic and dikaryotic hyphae ofCyathus olla Brodie,C. setosus Brodie andC. bulleri Brodie was investigated. In the homokaryotic hyphae a nucleolus develops within a globular condensed nucleus consisting of a folded up filament. As the nucleolus increases in size, the nucleus unfolds and can assume a ring, horseshoe or filament configuration. The filament duplicates and (usually when unwound from the nucleolus) divides longitudinally. Occasionally, strand separation occurs while the filament is wrapped in the form of a ring around the nucleolus. The daughter nuclei may condense before the next division. In the dikaryotic hyphae the same nuclear cycle occurs as in the homokaryons except that an extra nuclear condensation to the globular form can occur in both the clamp and tube nuclei. The division of these two nuclei is not always synchronous and, moreover, the stage of karyokinesis of the clamp nucleus is not closely synchronized with the formation of the clamp connection. A deeply stained granule is associated with the nucleus. Some granules can be observed to be connected to the nucleus by a faintly Feulgen positive thread-like structure but other granules are sessile. The granule or centriole-like body is thought to direct the nuclear unfolding process. It may divide prior to, or after nuclear division.     

Microtubule-driven nuclear movements and linear elements as meiosis-specific characteristics of the fission yeasts Schizosaccharomyces versatilis and Schizosaccharomyces pombe

Meiotic prophase in Schizosaccharomyces pombe is characterized by striking nuclear movements and the formation of linear elements along chromosomes instead of tripartite synaptonemal complexes. We analysed the organization of nuclei and microtubules in cells of fission yeasts undergoing sexual differentiation. S. japonicus var. versatilis and S. pombe cells were studied in parallel, taking advantage of the better cytology in S. versatilis. During conjugation, microtubules were directed towards the mating projection. These microtubules seem to lead the haploid nuclei together in the zygote by interaction with the spindle pole bodies at the nuclear periphery. After karyogamy, arrays of microtubules emanating from the spindle pole body of the diploid nucleus extended to both cell poles. The same differentiated microtubule configuration was elaborated upon induction of azygotic meiosis in S. pombe. The cyclic movements of the elongated nuclei between the cell poles is reflected by a dynamic and coordinated shortening and lengthening of the two microtubule arrays. When the nucleus was at a cell end, one array was short while the other bridged the whole cell length. Experiments with inhibitors showed that microtubules are required for karyogamy and for the elongated shape and movement of nuclei during meiotic prophase. In both fission yeasts the SPBs and nucleoli are at the leading ends of the moving nuclei. Astral and cytoplasmic microtubules were also prominent during meiotic divisions and sporulation. We further show that in S. versatilis the linear elements formed during meiotic prophase are similar to those in S. pombe. Tripartite synaptonemal complexes were never detected. Taken together, these findings suggest that S. pombe and S. versatilis share basic characteristics in the organization of microtubules and the structure and behaviour of nuclei during their meiotic cell cycle. The prominent differentiations of microtubules and nuclei may be involved in the pairing, recombination, and segregation of meiotic chromosomes.